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Coventry University
Coventry University Repository for the Virtual Environment (CURVE) Copyright © and Moral Rights for this thesis are retained by the author and/ or other copyright owners. A copy can be downloaded for personal non-commercial research or study, without prior permission or charge. This thesis cannot be reproduced or quoted extensively from without first obtaining permission in writing from the copyright holder(s). The content must not be changed in any way or sold commercially in any format or medium without the formal permission of the copyright holders. A NUMBER OF GRAPHS AND TABLES HAVE BEEN REMOVED FROM CHAPTER 1 FOR COPYRIGHT REASONS, INCLUDING APPENDIX 3.1.1 AND A PUBLISHED PAPER. PLEASE CONSULT THE DVDVERSION OR PRINTED VERSION IN THE LIBRARY. When referring to this work, full bibliographic details must be given: Tamaldin, N. (2010) ‘Experimental investigation of emissions from a light duty diesel engine utilizing
urea spray SCR system' Coventry University, PhD Thesis.
http://curve.coventry.ac.uk
Experimental Investigation of Emission from a Light Duty Diesel Engine Utilizing Urea
Spray SCR system
Noreffendy Tamaldin
PhD
June 2010
The work contained within this document has been submitted by the student in partial fulfilment of the requirement of their course and award
By
EXPERIMENTAL INVESTIGATION OF EMISSION FROM A LIGHT DUTY
DIESEL ENGINE UTILIZING UREA SPRAY SCR SYSTEM
NOREFFENDY TAMALDIN, M.Eng.
A thesis submitted in partial fulfilment of the University’s requirements for the
Degree of Doctor of Philosophy
JUNE 2010
ii
ACKNOWLEDGEMENTS
This thesis is the culmination of over three years of research at AEARG (Automotive Engineering
Applied Research Group), Coventry University. It is over three years of which I have survived only
through the help and understanding of many people. I would like to thank them here. First and
foremost, I would like to express my appreciation to the AEARG director who is also my supervisor
Professor S.F. Benjamin for offering me this enriching opportunity and experience to pursue my
Ph.D. I would also like express my gratitude for his untiring patience and encouragement when
obstacles and difficulties arise, guidance in my research, and for his good example that urges me
to progress academically and personally.
I would also like to convey my invaluable thanks to Dr. C. A. Roberts, for her indispensable
guidance and kind support, her involvement in the project, continuous advice, support and useful
discussions. Without all of these, this work may not have been completed. Special thank Dr. A.J.
Alimin for training me on setting up and running the test bed, analyzers and the Froude control
system. To Dr S. Quadri for calibration and setting up the Ricardo air flow meter. To Mr. R.
Gartside, thank you for his help during the commissioning of the engine, test bed and the engine
control system. To Mr E. Larch for the engine ECU programming and Gredi setup. To Mr S.
Goodall (Brico) for his technical advice. The technical help and assistance from, Mr C.
Thorneycroft, Mr. S Allitt, Mr. C. Roebuck and the late Mr. K.Smith are also appreciated and
acknowledged.
I am indebted to UTeM and MOHE (Ministry of Higher Education), Malaysia for providing the
financial support throughout my study and the following companies: Jaguar Land Rover, Johnson
Matthey Catalyst and Faurecia, for their technical provisions for the experimental works.
I cannot end without thanking my family on whose constant encouragement and love I have relied
throughout my study, especially my parents, Tamaldin Bahardin and Zaiton Husin for their love
and emotional support. My gratitude also goes to my Faculty Dean, Professor Dr Md. Razali Ayob,
for believing in me and his continuous moral support to make sure I complete my study.
Last but not least, my deepest love and appreciation to my dearest wife, Maseidayu Zolkiffili and
my wonderful kids, Ameer Husaini and Amaar Zuhasny, for their passion and suffering being with
me in the challenging weather and life in the UK throughout my study. They are all the reason I
continue improving myself being a better person for a better life.
iii
ABSTRACT Stringent pollutant regulations on diesel-powered vehicles have resulted in the development of new
technologies to reduce emission of nitrogen oxides (NOx). The urea Selective Catalyst Reduction (SCR) system
and Lean NOx Trap (LNT) have become the two promising solutions to this problem. Whilst the LNT results in a
fuel penalty due to periodic regeneration, the SCR system with aqueous urea solution or ammonia gas
reductants could provide a better solution with higher NOx reduction efficiency.
This thesis describes an experimental investigation which has been designed for comparing the effect NOx
abatement of a SCR system with AdBlue urea spray and ammonia gas at 5% and 4% concentration. For this
study, a SCR exhaust system comprising of a diesel particulate filter (DPF), a diesel oxidation catalyst (DOC) and
SCR catalysts was tested on a steady state, direct injection 1998 cc diesel engine. It featured an expansion can,
nozzle and diffuser arrangement for a controlled flow profile for CFD model validation. Four different lengths
of SCR catalyst were tested for a space velocity study. Chemiluminescence (CLD) based ammonia analysers
have been used to provide high resolution NO, NO2 and NH3 measurements across the SCR exhaust system. By
measuring at the exit of the SCR bricks, the NO and NO2 profiles within the bricks were found. Comparison of
the measurements between spray and gas lead to insights of the behaviour of the droplets upstream and
within the SCR bricks.
From the analysis, it was deduced that around half to three quarters of the droplets from the urea spray
remain unconverted at the entry of the first SCR brick. Approximately 200 ppm of potential ammonia was
released from the urea spray in the first SCR brick to react with NOx. The analysis also shows between 10 to
100 ppm of potential ammonia survived through the first brick in droplet form for cases from NOx-matched
spray input to excess spray. Measurements show NOx reduction was complete after the second SCR bricks.
Experimental and CFD prediction showed breakthrough of all species for the short brick with gas injection due
to the high space velocity. The long brick gas cases predictions gave reasonable agreement with experimental
results. NO2 conversion efficiency was found higher than NO which contradicts with the fast SCR reaction
kinetics.
Transient response was observed in both cases during the NOx reduction, ammonia absorption and desorption
process. From the transient analysis an estimate of the ammonia storage capacity of the bricks was derived.
The amount of ammonia slippage was obtained through numerical integration of the ammonia slippage curve
using an excel spreadsheet. Comparing the time constant for the spray and gas cases, showed a slightly faster
time response from the gas for both NOx reduction and ammonia slippage.
iv
TABLE OF CONTENTS
CHAPTER TITLE PAGE
ACKNOWLEDGEMENTS………………………………………………………………………. ii
ABSTRACT……………………………………….…………………………….………………..…. iii
TABLE OF CONTENTS……………………………………………………………………….…. iv
LIST OF TABLES …………………………………………………………..……………………... x
LIST OF FIGURES …………………………………………………………….……………….…. xi
LIST OF ABBREVIATIONS AND SYMBOLS……………………………………………... xiv
LIST OF APPENDICES …………………………………………………………….………….... xx
CHAPTER 1 : INTRODUCTION .............................................................................................. 1
1.0 Background of Air pollution. .................................................................................................. 1
1.1.1 History of Pollution ................................................................................................ 1
1.1.2 Diesel Emission Regulation. ................................................................................... 3
1.2 Motivation of this thesis ........................................................................................................ 4
1.2.1 Aims and Objectives ............................................................................................... 4
1.2.2 Thesis Organisation ................................................................................................ 5
CHAPTER 2 LITERATURE REVIEW......................................................................................... 6
2.0 Diesel After-treatment on NOx Emission Overview .............................................................. 6
2.1 Principle of Operation: Selective Catalyst Reduction (SCR) ................................................... 6
2.2 Diesel Oxidation Catalyst (DOC) and Diesel Particulate Filter (DPF) ...................................... 8
2.2.1 Effect of NO2/NO ratio on NOx conversion. ........................................................... 12
2.3 SCR Catalyst types .................................................................................................................. 13
2.3.1 Platinum catalysts .................................................................................................. 13
2.3.2 Vanadia Titania Catalysts ....................................................................................... 14
2.3.3 Zeolite Catalyst....................................................................................................... 14
v
2.3.3.1 High Temperature Zeolite ...................................................................... 14
2.3.3.1 Low temperature Zeolite ....................................................................... 15
2.3.4 Comparison of SCR catalysts. ................................................................................. 16
2.4 SCR reductants ....................................................................................................................... 17
2.4.1 Aqueous Ammonia ................................................................................................. 17
2.4.2 Anhydrous ammonia. ............................................................................................. 20
2.5 Challenges in automotive SCR. .............................................................................................. 20
2.5.1 Ammonia slip ......................................................................................................... 21
2.5.2 Uniform mixing of Urea. ........................................................................................ 21
2.5.4 Space velocity ........................................................................................................ 22
2.5.5 Light duty diesel engine study ............................................................................... 22
2.5.6 Urea spray droplet modelling ................................................................................ 22
CHAPTER 3: RESEARCH METHODOLOGY ............................................................................. 25
3.0 Introduction ........................................................................................................................... 25
3.1 Engine Commissioning and Setup .......................................................................................... 25
3.1.1 Engine Commissioning and Setup for Steady State Test. ...................................... 25
3.1.2 Engine Dynamometer ............................................................................................ 27
3.1.3 Engine mass flow rate measurement .................................................................... 27
3.2 Final SCR Exhaust build and commissioning. ......................................................................... 28
3.2.1 SCR Exhaust Fabrications and Specifications. ........................................................ 30
3.2.2 DPF-DOC assembly. ................................................................................................ 30
3.2.3 SCR Catalysts Assembly .......................................................................................... 31
3.2.4 Urea Spray Mixing Chamber .................................................................................. 32
3.2.5 Instrumentation module assembly. ....................................................................... 33
3.2.6 Long and short diffuser assembly .......................................................................... 34
3.2.7 Bypass pipe assembly. ........................................................................................... 34
3.2.8 DPF Monitoring and Preconditioning .................................................................... 34
vi
3.2.10 SCR Catalyst Monitoring and Preconditioning ..................................................... 35
3.3 EXSA 1500 NOx Analyser Setup ............................................................................................. 35
3.3.1 EXSA 1500 Specifications and Resolutions ............................................................ 35
3.3.2 Gas requirements and Calibration Gases .............................................................. 36
3.3.3 NOx measurement procedure ............................................................................... 37
3.4 Ammonia analyser MEXA 1170Nx ......................................................................................... 38
3.4.1 MEXA1170Nx Specification and Resolution. .......................................................... 39
3.4.2 MEXA 1170Nx Gas Requirements and Calibration. ............................................... 40
3.4.3 MEXA 1170Nx Working Principles ......................................................................... 43
3.4.3a Working Principle of Chemiluminescence (CLD) ..................................... 43
3.4.3b Interference of CO2 and H2O ................................................................... 44
3.4.3c Measurement of NOx .............................................................................. 44
3.4.4 NOx measurement in NH3 mode. .......................................................................... 45
3.4.5 NO2 measurement in NO2 mode. ........................................................................... 45
3.5 ETAS Lambda Meter ............................................................................................................... 46
3.6 Urea Spray Setup ................................................................................................................... 47
3.6.1 Urea Spray Calibration ........................................................................................... 48
3.6.2 Urea Spray Pulse Length Setting Procedure .......................................................... 49
3.6.3 Engine NOx Out Mapping ...................................................................................... 49
3.6.4 The Urea Spray Layout and Experimental Procedure ............................................ 52
3.6.5 Spray Setting and Cleaning Procedures. ................................................................ 54
3.6.6 Deposit build up on Spray ...................................................................................... 56
3.6.7 Cleaned Spray inspection ....................................................................................... 57
3.7 NH3 Gas Experimental Setup .................................................................................................. 59
3.7.1 NH3 Gas Supply and Nozzle Location. .................................................................... 59
3.7.2 Gas flow meter and pressure gauge. ..................................................................... 60
3.7.3 NH3 gas experimental layout. ................................................................................ 61
vii
3.7.4 NH3 Gas Experimental Procedure. ......................................................................... 62
3.8 NO/NO2 measurement for DPF-DOC arrangement. .............................................................. 63
3.8.1 DOC-DPF configuration. ......................................................................................... 63
3.8.2 DPF-DOC configuration. ......................................................................................... 64
3.9 Measurement using various sampling probe length. ............................................................ 66
3.10 Problems associated with the MEXA Analyser .................................................................... 68
3.11 Final measurement strategies. ............................................................................................ 73
3.12 Summary of final experimental procedures. ....................................................................... 76
3.13 Example of measurements strategy applied ....................................................................... 77
CHAPTER 4: EXPERIMENTAL RESULTS AND DISCUSSIONS .................................................... 79
4.0 Experimental results: Introduction ........................................................................................ 79
4.1.0 Urea spray studies: General overview ................................................................... 79
4.1.1 Urea spray studies: Upstream Measurements (1 and 4 SCR bricks) ..................... 80
4.1.2 Urea spray studies: Downstream Measurements (1 and 4 SCR bricks) ................. 80
4.1.3 Urea spray studies: Deduced value........................................................................ 81
4.1.4 Urea sprays studies: Ammonia levels. ................................................................... 81
4.1.5 Measurement with Urea Spray and 1 SCR bricks. ................................................. 82
4.1.6 Measurement with Urea Spray and 4 SCR bricks. ................................................. 83
4.2 Ammonia gas studies: General Overview .............................................................................. 84
4.2.1 Ammonia gas studies: upstream measurements. (1 and 4 SCR bricks) ................. 84
4.2.2 Ammonia gas studies: downstream measurements. (1 and 4 SCR bricks) ............ 85
4.2.3 Ammonia gas studies: Deduced values.................................................................. 85
4.2.4 Ammonia gas studies: Ammonia levels ................................................................. 86
4.2.5 Measurement with 5% Ammonia Gas and 1 SCR brick. ........................................ 87
4.2.6 Measurement with 5% Ammonia Gas and 2 SCR bricks. ....................................... 87
4.2.7 Measurement with 5% Ammonia Gas and 3 SCR bricks. ....................................... 88
4.2.8 Measurement with 5% Ammonia Gas and 4 SCR bricks. ....................................... 89
viii
4.2.9 Measurement with 4% Ammonia Gas and 1 SCR bricks. ....................................... 90
4.3 Analysis of measurement results against ammonia input/potential ammonia input. .......... 91
4.4 Analysis of spray compared to gas ......................................................................................... 92
4.5 Analysis of insight behaviour of droplet from the urea spray. .............................................. 93
4.5.1 Ammonia released from urea spray upstream of the SCR bricks. ......................... 93
4.5.2 Ammonia released from urea spray within the 4 SCR bricks................................. 94
4.5.3 Ammonia passing through 1 SCR brick in droplets form. ...................................... 94
4.6 Analysis of NO and NO2 conversion efficiency and ammonia slip. ........................................ 95
4.6.1 NO conversion efficiency ....................................................................................... 96
4.6.2 NO2 conversion efficiency ...................................................................................... 97
4.6.3 Comparison of NO and NO2 conversion. ................................................................ 98
4.6.4 Ammonia slip. ........................................................................................................ 99
4.7 CFD modelling analysis comparison with measurements. .................................................... 100
4.7.1 CFD data comparison with ammonia gas injection for 1 SCR and
4 SCR bricks. ............................................................................................................. 101
4.8 Comparison of CFD prediction with NO2, NO and NH3 at the SCR exit. ................................. 102
4.8.1 CFD prediction comparison of NO2 with measurement results............................. 102
4.8.2 CFD prediction comparison of NO with measurement results. ............................. 103
4.8.3 CFD prediction comparison of NH3 with measurement results. ............................ 103
4.8.4 Overall remark from CFD comparison with measurements. ................................. 104
4.9 Transient analysis in the investigation. .................................................................................. 105
4.9.1 Transient analysis of 4 SCR bricks with 4% NH3 gas. .............................................. 105
4.9.1.1 Time constants for gas. .......................................................................... 108
4.9.2 Transient analysis of 4 SCR brick with urea spray .................................................. 109
4.9.2.1 Time constants for urea spray. .............................................................. 111
4.9.3 Comparison of the urea spray and ammonia gas transients. ................................ 111
4.10 Summary of the experimental and simulation results. ....................................................... 112
ix
CHAPTER 5 CONCLUSIONS AND FUTURE WORK .................................................................. 114
5.0 Conclusions and Future work: Introduction. ......................................................................... 114
5.1 DPF-DOC arrangement. .......................................................................................................... 114
5.2 Experimental techniques. ...................................................................................................... 114
5.3 Behaviour of urea droplet from spray. .................................................................................. 115
5.4 Space velocity and resident time effect. ................................................................................ 115
5.5 Transient observation and storage. ....................................................................................... 115
5.6 Significant of findings in chapter 4 ......................................................................................... 116
5.7 Contributions to the knowledge ............................................................................................ 116
5.8 Recommendation for Future Work. ....................................................................................... 117
5.8.1 Improved gas analyser to measure NOx in presence of ammonia. ....................... 117
5.8.2 Spray dosing system............................................................................................... 117
5.8.3 Cleaning of spray or continuous spraying .............................................................. 118
5.8.4 Improved warm up and system using sequential program. .................................. 118
5.8.5 Signal trigger improvement with level differentiation of spray pulses and
gas settings. .......................................................................................................... … 118
5.8.6 Investigation of effect of spray angle and positions. ............................................. 118
5.8.7 Moving from 1D to 3D flow ................................................................................... 118
5.8.8 Transient study (acceleration and deceleration) ................................................... 119
5.8.9 Engine Mass flow rate measurement and logging................................................. 119
REFERENCES ...................................................................................................................... 120
APPENDICES ...................................................................................................................... 134
x
LIST OF TABLES
TABLE TITLE PAGE
1.1.2 Evolution of European emission regulations (reproduced from DieselNet 2010)...… 3
2.3.1 Various SCR Catalyst Temperature range. ……………………………………………………….……. 16 3.1.1 Diesel Engine specification used for investigation (Ford 2FM series) ………….………… 26 3.2.2 Detail specification of the DOC catalyst………………………………………………………………… 31 3.2.3 Detail specification of the SCR catalyst…………………………………………………………….…… 32
3.3.1 Technical Specifications of EXSA 1500 Common gas analyser [Extracted from the Horiba Ltd, EXSA 1500 operating manual Oct 2004] ……………… 36
3.4.2 Gas Requirement for MEXA-1170Nx Analyser. …………………………..……………….………… 40 3.8.1 NO/ NO2 ratio based on DOC-DPF assembly. ………………………………………………..……… 64 3.10a MEXA analyser performance when measuring a mixture of NO, NO2 and NH3….…… 72 3.11a Measurement strategy when using Horiba MEXA 1170Nx ammonia analyser………. 75 3.11b Experimental test matrix with urea spray and NH3 gas………………………………………….. 76 4.1.5 Summary of Result: Urea Spray with 1 SCR. ……………………………..…………………………… 82
4.1.6 Summary of Result: Urea Spray with 4 SCR. ………………………….………………………………. 83
4.2.5 Summary of Result: 5% Ammonia Gas with 1 SCR. ……………………………………………….. 87
4.2.6 Summary of Result: 5% Ammonia Gas with 2 SCR. ……………………………………………… 88
4.2.7 Summary of Result: 5% Ammonia Gas with 3 SCR. ……………………………………………… 89
4.2.8 Summary of Result: 5% Ammonia Gas with 4 SCR. ……………………………………………… 90
4.2.9 Summary of Result: 4% Ammonia Gas with 1 SCR………………………………………………… 91
4.6.1 Space velocity for SCR bricks used in the investigation. ………………………………………… 97
4.9.3 Comparison of the 4% gas with urea spray transient analysis. ……………………………… 112
xi
LIST OF FIGURES
FIGURE TITLE PAGE
1.1.1 Increasing popularity of diesel powered vehicle in the United Kingdom (reproduced
from SMMT Motor Industry Fact 2010)………………………………….…..…….……..…..….……...... 2
1.1.2 Euro 6 (2014) LDD NOx regulations compared to US Tier 2 Bin 5 and California SULEV
(Bin2). [Johnson T.V. 2009]…………………..…….……..…..….……....…..…….……..…..…..……........ 4
2.1 SCR system configurations with open loop urea SCR system [DieselNet 2005]……….…… 8
2.2 Wall-Flow DPF [reproduced from Heck 2009] ..……..…………………….…………………..…………. 9
2.2a Possible architecture for NOx/PM control.……..……………………..….……...……..……………..…. 10
2.2b Schematic of an advance diesel after treatment system architecture compared in
Gurupatham et al (2008) .……..……………………..….…..……..……….………………..……………..…... 10
2.2c Advance diesel after treatment system with SCRF concepts [Guo et al 2010] ……….……. 11
2.2.1a Effect of NO2/NO ratio on NOx conversion in V2O5/TiO2 catalyst ……………………….……….. 12
2.2.1b Effect of NO2 from DOC on NOx conversion……………………………………………………………….… 13
2.3 Comparison of SCR catalyst operating temperature windows [Walker 2005]……………... 16
2.4.1a Urea solution freezing point [BASF 2003]……………………….…………………………………………... 19
2.4.1b Urea solution 32.5% decomposition [BASF 2003]……………………………………………………….. 19
3.1.1 The 2FM series engine with Injection Control Unit (ICU) and Engine Control Unit (ECU)
on Froude Consine AG150 engine dynamometer…………………….……..………………………..…. 26
3.1.4 Ricardo mass flow meter measuring engine Mass Flow Rate (MFR)……….………………….… 28
3.2 Final assembly of the SCR exhaust system………………………………….……………………………….. 29
3.2.1 The suspended exhaust from a square metal frame.…………………………..….…………………... 30
3.2.4 The Urea spray mixing chamber……………………………………….…….……..………………………….... 32
3.2.5 Instrumentation modules location along the SCR exhausts system………….……..………….. 33
3.3.2 EXSA 1500 NOx analyzer gas piping configuration……………………….……..……………………….. 37
3.4 The MEXA-1170Nx NH3 analyzer unit………………………………………….……..……………………….. 39
3.4.2 Gas piping Layout for MEXA-1170NX ammonia analyzer……………….……..……………..……… 41
3.3.4 Process flow of MEXA-1170NX daily operation and calibration……….……………………..…… 42
3.4.4 NH3 mode of MEXA-1170NX analyzer…………………………………….……………………………….….. 45
3.4.5 NO2 mode of MEXA-1170NX analyzer…………………………………….……..……………………………. 46
3.5 ETAS LA4 Lambda meter used to measure O2 before and after the SCR catalysts……..… 47
3.6 Schematic of a manual urea spray system.…………………………..…………………………………..… 47
xii
3.6.1 Calibration chart of mass flow rate (mg/s) against spray pulse length (ms)
[courtesy Dr C.A. Roberts]…………………………..…………………………………………………………….… 48
3.6.2 Chart showing estimated urea/AdBlue (g/s) required against engine NOx out (ppm)…. 49
3.6.3a Engine NOx out based on load BMEP (bars), speed (RPM) and EGR ON……………………... 50
3.6.3b Exhaust Mass Flow (g/s) based on load, BMEP (bars), speed (RPM) and EGR ON……….. 50
3.6.4a Urea AdBlue injector testing prior to experimental with spray system………………………… 52
3.6.4b Urea Spray injector and supply pipes and wiring in place………………………………………….… 53
3.6.4d Urea spray system experimental layout………………………………………………………………………. 54
3.6.5a Spray cleaning procedures flow chart……………………………………….…………………………………. 55
3.6.6 White deposit build up and ultrasonic cleaning…………………………………………………………... 56
3.6.6e Manual cleaning of injector sleeve with tweezers…………………………...………………………….. 57
3.6.7 Final visual inspection of fully cleaned injector…………………………….……………………………... 58
3.7.1b NH3 gas injection nozzle…………………………………………………...……………………………………….… 60
3.7.2 Gas flow meter reading as a guide. …………………………………………………………………………….. 61
3.7.3 NH3 gas experimental layout…………………………………………………..…………………………………... 62
3.8.1 Initial configuration with DOC-DPF assembly.…………………………..……………………………….… 64
3.8.2 Final DPF-DOC assembly…………………………..…………………………………………………………………. 65
3.9a Variation of sampling probe length for profile measurement……………………………….…….. 66
3.9b Long (55 mm) sampling probe…………………………..………………………………………………………… 67
3.9c Medium (25 mm) sampling probe…………………………..…………………………………………………... 67
3.9d Check point with medium sampling probe for gas measurement.……………….…………….… 68
3.10a Rubber seal disintegrate in the SUM NOx converter.…………………………………………..…….… 69
3.10.1b Paper based finger filter located at the back of MEXA 1170Nx ammonia analyser……... 69
3.10c Spherical carbon compact NOx converter…………………………..….………………………….………… 70
3.10d New glassy carbon NOx converter…………………………..………….…………………………………….… 70
3.10e A typical example of erroneous measument of NOx in present of ammonia……………..… 71
3.13 Example of engine log from 5% ammonia gas with 1 scr brick.…………….……………………… 78
4.1a Typical example of erroneous measument of NOx in present of ammonia.………...……… 78
4.3 Summary of measurement with 1 and 4 SCR bricks.…………………..……………………………….. 92
4.5.1 Ammonia released from spray upstream of the SCR bricks……………………….………………… 93
4.5.2 Ammonia released from urea spray within 4 SCR bricks.………………..…………………………… 94
4.5.3 Ammonia passing through 1 SCR brick in droplets form. …………………….…….……………… 95
4.6.1 NO conversion with respect to SCR length……………….....…..………………..…………………… 96
4.6.2 NO2 conversion with respect to SCR length.…………………………..………………..……………… 98
xiii
4.6.3 Comparison of NO and NO2 conversion efficiency.…………..………………….….….…………… 99
4.6.4 Ammonia slip against potential ammonia input with respect to SCR brick length....… 100
4.7.1a CFD and data comparison for species level at exit from 1 SCR brick.……………..………… 101
4.7.1b CFD and data comparison for species levels at exit from 4 SCR bricks.……………………… 101
4.8.1 Simulations of NO2 against measurements at SCR exit. …………………………………………… 102
4.8.2 Simulations of NO against measurements at SCR exit. …………………………………….………. 103
4.8.3 Simulations of NH3 against measurements at SCR exit. …………………………………….……… 104
4.9.1 Sample of transient response in 4 SCR bricks with 4% NH3 gas…………………………………… 105
4.9.1a Transient analysis for 4% gas with 4 SCR…………………………..…………………………..………… 106
4.9.2 Transient analysis for urea spray with 4 SCR…………………………..…………………..…………… 109
xiv
LIST OF ABBREVIATIONS AND SYMBOLS
α - Alpha – ratio of NH3 : NOx
λ - Ratio between actual AFR and stoichiometric AFR
ACEA - European Automobile Manufacturers Association
AdBlue - Registered trademark for AUS32 (Aqueous Urea Solution 32.5%)
AEARG - Automotive Engineering Applied Research Group, Coventry University
AFR - Air Fuel Ratio
Al+3 - Aluminium cations
Al2(SO4)3 - Aluminium Sulfate
Al2O3 - Aluminium Oxide
AMI - AdBlue supplier - Agrolinz Melamine International (Austria)
Anatase - One of the three mineral forms of titanium dioxide, the other two being
brookite and rutile. It is always found as small, isolated and sharply
developed crystals, and like rutile, a more commonly occurring modification
of titanium dioxide, it crystallizes in the tetragonal system.
ARB - Air Resource Board
ASAM - Association for Standardization of Automation and Measuring Systems
AUS32 - Aqueous Urea Solution 32.5% by weight.
BaO - Barium Oxide is a white Hygroscopic Compound Formed by the Burning of Barium in Oxigen.
BASF - AdBlue supplier, German Chemical Company,
Badische Anilin und Soda Fabrik (Baden Anilin and Soda Factory)
Bhp-hr - Brake horse power-hour (typical unit for emission in the United States)
xv
BMEP - Brake Mean Effective Pressure (bar)
BSP - British Standard Pipe Taper thread
CAE - Computer Aided Engineering
CAFE - Corporate Average Fuel Economy
CAL - Calibration
CAN - Controller Area Network (computer network protocol and bus standard
designed to allow microcontrollers and devices to communicate with each
other and without a host computer.)
CARB - California Air Resource Board
CEFIC - European Chemical Industry Council
CFD - Computational Fluid Dynamics
CLD - Chemiluminescence Detector
CNG - Compressed Natural Gas is a fossil fuel substitute for gasoline (petrol),
diesel, or propane fuel.
CO - Carbon Monoxide
CO2 - Carbon Dioxide
CRT - Continuously Regenerating Technology filter
Cu - Copper
DEF - Diesel Exhaust Fluid
DIN 70070 - German Industrial Standard on Specification of SCR Urea Grade,
(DIN- Deutsches Institut für Normung. German Institute for Standardization)
DOC - Diesel Oxidation Catalysts
DPF - Diesel Particulate Filters
dSPACE - A software package integrated with Matlab Simulink use to control the
throttle body of an engine.
xvi
ECE R49 - European Cycle Emission Revision 49
ECU - Engine Control Unit
EEC(CED) - European Commission Directive
EGR - Exhaust Gas Recirculation
EMS - Engine Management System
EPA - Environmental Protection Agency, United States
ESC - European Steady Cycle
FAN MOG Fleet Average Non-methane Organic Gases
FBC - Fuel Borne Catalyst
GHG - Green House Gases
GREDI - Engine ECU calibration software from Kleinknecht Automotive GmbH
GVWR - Gross Vehicle Weight Rating
H2O - Water
HC - Hydrocarbon
HLDT - Heavy light-duty trucks
HNCO - Isocyanic Acid
ICU - Injection Control Unit
JAMA - Japan Automobile Manufacturers Association
JARI - Japan Automotive Research Institute
kW - Kilowatt (Power)
LDD - Light Duty Diesel
LDT - Light Duty Truck
LDV - Light Duty Vehicles
xvii
LEV - Low Emission Vehicle
LEV II - Low Emission Vehicle II
LLDT - Light light-duty Trucks
LNT - Lean NOx Trap
LPG - Liquid Petroleum Gas
MAF - Intake air Mass Air Flow
MECA - Manufacturer of Emissions Control Association
MKT - Market
MLW - Maximum Laden Weight
MoO3 - Molybdenum trioxide
N2 - Nitrogen gas
NAAQS - National Ambient Air Quality Standard
NGV - Natural Gas Vehicle
NH2 - Amines are organic compounds and functional groups that contain a basic
nitrogen atom with a lone pair
NH3 - Ammonia
NH4 - Ammonium cation (also known as ionized ammonia)
NMHC - Non-methane Hydro Carbon. All Hydrocarbons excluding methane.
NMOG - Non- methane Organic Gases. All Hydrocarbons and Reactive Oxygenated
Hydrocarbon Species such as Aldehydes, but excluding Methane
NOx - Nitrogen Oxides ( NO and NO2)
NPT - National Pipe Thread Tapered Thread (NPT) is a U.S. standard for tapered
threads.
O2 - Oxygen gas
xviii
O3 - Ozone
OEHHA - The Office of Environmental Health Hazard Assessment (California EPA)
OGU - Ozone Generator Unit
Pb - Lead
PEL - Permissible Exposure Level
PM - Particulate Matters
ppm - Parts per million
Pt - Platinum
PZEV - Partial Zero Emission Vehicle.
RPM - Speed in Revolution per Minute
Rutile - Mineral composed primarily of titanium dioxide, TiO2.
SAE - Society of Automotive Engineers
SAE J1088 - SAE J1088 - Test Procedure for the Measurement of Gaseous Exhaust
Emissions From Small Utility Engines
SCR - Selective Catalyst Reduction
SCRF - Combination of SCR and DPF with SCR washcoat on a DPF (Ford Motor)
SMMT - Society of Motor Manufacturers and Traders, UK Limited.
SO2 - Sulphur Dioxides
SO3 - Sulphur Trioxides
SOF - Organic Fraction of Diesel Particulates
STAR-CD - A CFD software package from CD-Adapco
SULEV - Super Ultra Low Emission Vehicle
SUV - Sport Utility Vehicle
xix
T&E - Transport and Environment
TiO2 - Titanium Dioxide
TLEV - Transitional Low Emission Vehicle.
ULEV - Ultra Low Emission Vehicle
UN ECE - United Nation European Cycle Emission
US, EPA - United States, Environmental Protection Agency
V2O5 - Vanadium Oxides
VGT - Variable Geometry Turbocharger
VPU - Vacuum Pump Unit
WHTC - World Harmonized Transient Cycle
WO3 - Tungsten trioxide
ZSM-5 - Zeolite Sieve of Molecular Porosity (or Zeolite Socony Mobil)-5. It is a
synthetic zeolite.
xx
LIST OF APPENDICES
APPENDIX
Reference section numbered in thesis
TITLE PAGE
3.1.1 Power curve for Ford 2.0 cc diesel engine A-1
3.1.3 Ricardo mass flow meter calibration A-2
3.2 Supplied parts for SCR exhaust build A-3
3.2b List of drawing for SCR exhaust system A-4
3.4.1 MEXA 1170Nx specification A-5
3.5 Lambda sensor LA4 connection configuration A-6
3.6.2 Potential ammonia released from urea spray calculation A-7
3.7a Calibration chart for NH3 gas flow rate using glass float A-8
3.7b Calibration chart for NH3 gas flow rate using stainless steel float A-9
3.7.1 Summary of gas flow rate with 4% and 5% ammonia in balance N2 A-10
3.7.1a Calculation of gas flow rate with 4% ammonia in N2 with steel float A-11
3.7.1b Calculation of gas flow rate with 4% ammonia in N2 with glass float A-12
3.7.1c Calculation of gas flow rate with 5% ammonia in N2 with steel float A-13
3.7.1d Gas flow setting/spray setting vs. ammonia level produced A-14
4.0 List of appendices from chapter 4 : Experimental Results B-1
4.1.5 Result from Urea spray : 1 SCR B-2
4.1.5b SUM in and SUM out average for 1 SCR with spray B-3
4.1.6 Result from Urea spray : 4 SCR B-4
4.1.6b SUM in and SUM out average for 4 SCR with spray B-5
4.2.5 Result from 5% Gas : 1 SCR B-6
4.2.5b NO dw 1SCR 5% : manual log from MEXA B-6b
4.2.6 Result from 5% Gas : 2 SCR B-7
4.2.7 Result from 5% Gas : 3 SCR B-8
4.2.8 Result from 5% Gas : 4 SCR B-9
4.2.9 Result from 4% Gas : 1 SCR B-10
4.9.1a Excel numerical integration – 4% gas 4 SCR B-11
4.9.2a Excel numerical integration – Urea spray 4SCR B-12
5.0 Publication : SAE World Congress April 2010 Experimental Study of SCR in a Light-Duty Diesel Exhaust to Provide Data for Validation of a CFD Model Using the Porous Medium Approach (SAE 2010-01-1177)
C-1
Chapter 1: Introduction
1
CHAPTER 1: INTRODUCTION
1.0 Background of Air pollution.
At present, there are many sources of air pollution from the combustion of fossil fuel for power
plants, factories, office building, transportation and other. Air pollution can have a large negative
impact on human health and the environment. The United States environmental protection agency
(EPA) has identified six common pollutants including Ozone (O3), Particulate Matter (PM), Carbon
Monoxide (CO), Sulphur Dioxide (SO2), Lead (Pb) and Nitrogen Oxides (NOx). The sum of nitric oxide
(NO) and NO2 is commonly called nitrogen oxides or NOx. Over the past decade, NOx emissions have
become one of the concerns due to its health impact to human. Various studies have been
conducted by numerous agencies around the world to evaluate the negative impact of NOx emission
to human health. The World Health Organization (WHO, 2002) estimated that around 2.4 million
people die every year linked to causes directly attributable to air pollution. A study at Birmingham
University also revealed a strong correlation between deaths by pneumonia and traffic emissions in
England. (Knox, E.G. 2008)
1.1.1 History of Pollution
The environmental impact of automotive pollution has led governments to enforce automotive
manufacturers to reduce quantities of tail-pipe emissions. Developments of the modern automotive
catalytic converter and engine management systems have been in response to these requirements.
There are an increasing number of vehicles in the world today with an estimate at around 800
million [Preschern et al, 2001]. The history of the new vehicle population over a ten year period in
the United Kingdom shows the growing popularity of diesel powered vehicles over petrol since 2003.
This is shown in figure 1.1.1. The rise of fuel prices and the advantages of diesel-powered vehicles in
term of fuel efficiency have driven this trend.
Chapter 1: Introduction
2
Figure 1.1.1 Increasing popularity of diesel powered vehicle in the United Kingdom (reproduced from
SMMT Motor Industry Fact 2010)
1.1.2 Diesel Emission Regulation.
Diesel Emission control began in the mid 1980’s when the United States, Environmental Protection
Agency (EPA) and California Air Resource Board (CARB) starting to consider emission from on road
vehicles. It started after a growing popularity of diesel engine patented by Rudolf Diesel in 1892 for
replacing steam engines. In the past, only Carbon Monoxide (CO) and Hydrocarbon (HC) emission
from gasoline engines were regulated [Heck, 2009].
The Three-Way catalytic (TWC) converter technology that has been successfully used on spark
ignition internal combustion engines operating at stoichiometric air-fuel ratio(typically fuelled by
petrol but also sometimes fuelled by LPG, CNG, or ethanol) since the middle 1980s will not function
at O2 levels in excess of 1.0%, and do not function well at levels above 0.5%. Since diesels operate
with excess oxygen, TWC cannot be utilized to reduce NOx and alternative after treatment
technology must be used.
Chapter 1: Introduction
3
In developed countries, automobiles must comply with statuary emission regulation to stay road-
worthy. These are measured over a standard drive-cycle, typical of mixed driving conditions. A
summary of the evolution of European emissions standards shows that future legislation will place
even tighter restrictions on automotive emissions with Euro 6 NOx level at only 0.08 g/km. The
evolution of European emission regulations is shown in the table 1.1.2.
Table 1.1.2 Evolution of European emission regulations (reproduced from DieselNet 2010)
Future legislation cannot be achieved in a cost-effective manner with current diesel after treatment
technology; consequently, the prospect of reducing emissions without substantially increasing
vehicle cost is attractive to manufacturers. Therefore, significant efforts have been driven to further
improve the diesel after treatment. Automotive manufacturers have been tested with reducing NOx
emissions especially for the latest Euro 6, US Bin 5 and California SULEV regulations.
Chapter 1: Introduction
4
Figure 1.1.2 Euro 6 (2014) LDD NOx regulations compared to US Tier 2 Bin 5
and California SULEV (Bin2). (Johnson T.V. 2009)
1.2 Motivation of this thesis
The main motivation in this investigation is that the collaborating automotive manufacturers
working with the Automotive Engineering Applied Research Group (AEARG) at Coventry University
are required to find a cost effective diesel after treatment system to further reduce NOx pollution
from light duty diesel powered passenger cars.
1.2.1 Aims and Objectives
The thesis aims and objectives are:
• To investigate the SCR performance on a Light Duty Diesel (LDD) engine.
Most of the current SCR investigations are focused on Heavy Duty Diesel (HDD) engines. This
investigation will provide information on the light duty diesel segment.
Chapter 1: Introduction
5
• To utilized zeolite in the SCR exhausts system.
Relatively few studies have been conducted on zeolite catalysts. Historically vanadium catalysts have
been used for SCR.
• To develop a unique test facility and provide a database for CFD validation.
The SCR exhaust system built in this investigation provides an excellent opportunity for assessing the
performance of simulation models.
• To develop a simplified controlled SCR exhaust system with real engine on test bed.
Most of SCR investigations use laboratory reactor and very little information is available from SCR
system on real engine test beds. The experience gained in this investigation will be useful for future
development.
1.2.2 Thesis Organisation
The organization of the thesis corresponds to the four objectives above.
Chapter 2 reviews current understanding of SCRs and examines the relation between NOx reduction
and NO/NO2 ratio.
Chapter 3 addresses the setting up of experiments, instrumentation and test protocol in order to
achieve the objectives above.
Chapter 4 presents and discusses the results obtained from the ammonia gas and urea spray
experiments.
Finally, Chapter 5 summarized the contribution of this research to new knowledge and future work
is proposed.
Chapter 2 Literature Review
6
CHAPTER 2: LITERATURE REVIEW
2.0 Diesel After-treatment for NOx reduction
Recent advancement in diesel after-treatment has identified two key promising technologies for
reducing d iesel emission which are t he Lean N Ox Trap ( LNT) an d S elective C atalyst Reduction
(SCR) [ Spurk et al., 2007]. D espite much research, improvements are n eeded in c onversion
efficiency across wider temperature ranges.
Alimin et al., (2006) explored the performance of an LNT at the Automotive Engineering Applied
Research Group (AEARG), Coventry University. Whilst good NOx reduction was achieved the LNT
system results in a fuel penalty due to regeneration period where rich combustion is needed to
purge th e tr ap. I n c ontrast, th e S CR s ystem p rovides a n a lternative solution wi thout an
associated fuel penalty.
2.1 Principle of Operation: Selective Catalyst Reduction (SCR)
Selective catalytic reduction (SCR) is a means of removing nitrogen oxides, through a c hemical
reaction between the exhaust gases, a (reductant) additive, and a catalyst. Beeck et al., (2006)
suggested the use of gaseous or liquid reductant (most commonly urea or AdBlue) to be added
to a stream of exhaust gas and absorbed onto a SCR catalyst. The reductant reacts with NOx in
the exhaust stream to form harmless H2O (vapour) and N2.
Three main processes involved in the SCR technology involve thermal decomposition, hydrolysis
and three NOx reduction SCR reactions. The three SCR reactions involved are Fast SCR, Standard
SCR and Slow SCR reaction.
Koebel, M. et al., (2000) and Yim, S.D. et al., (2004) suggested th at th ermal d ecomposition
occurred as the urea water solution is injected in the hot exhaust stream as below.
Chapter 2 Literature Review
7
Urea d roplets from the s pray e xchange m ass, momentum a nd e nergy with s urroundings h ot
exhaust gases leading to vaporization of water.
NH2-CO-NH2 (aqueous) NH2 – CO-NH2 (solid) + 6.9H2O (gas) Equation 2.1a
Schaber et al., (2004) reported that the Solid u rea l eft f rom eq uation 2.1a started m elting at
1330C and undergoes thermolysis to form ammonia and Isocyanic acid as follows:
NH2 – CO-NH2 (solid) NH3 (gas) + HNCO (gas) Equation 2.1b
Yim S.D. et al., (2004) also s uggested t he h ydrolysis o f I socyanic ac id is fa cilitated b y h igh
temperatures a t a round 400oC in t he p resence of a S CR c atalyst. The I socyanic acid w hich is
stable in g as f orm u ndergoes h ydrolysis t o f orm a mmonia an d c arbon d ioxide as s hown in
equation 2.1c.
NHCO (gas) + H20 (gas) NH3 (gas) + CO2 (gas) Equation 2.1c
Olsson et al., (2008) reported once th e N H3 gas i s av ailable, t he t hree N Ox re duction S CR
reactions take place depending on the NOx source. The standard SCR using NO, Fast SCR with
NO, NO2 and slow SCR with only NO2 as follows:
(Standard SCR) 4NH3 + 4NO + O2 4N2 + 6H2O Equation 2.1d
(Fast SCR ) 2NH3 + NO + NO2 2N2 + 3H2O Equation 2.1e
(Slow SCR) 4NH3 + 3NO2 3.5N2 + 6H2O Equation 2.1f
Amon et al., (2004) reported good N Ox c onversion efficiency with th e S CR system i n bo th
stationary and transient test cycle of Japanese, European and US test cycle.
Tennison et al., (2004) investigations on l ight d uty S CR w ith ze olite showed good N Ox
conversion le vel of over 90% for cold s tart FTP-75 and over 80% for the US06 cycle. A c losed
couple DOC was used to convert a portion of NO to NO2. It was suggested that a mixture of NO
and NO2 enhanced low temperature NOx conversion in light duty application.
Chapter 2 Literature Review
8
Various S CR c onfigurations have b een u sed b y d ifferent re searchers and o ngoing d evelopment i s
still u nderway e specially f or li ght d uty ap plication. A t ypical u rea S CR s chematic f or h eavy d uty is
shown i n f igure 2 .1
Figure 2.1 SCR system configurations with open loop urea SCR system [DieselNet 2005].
2.2 Diesel Oxidation Catalyst (DOC) and Diesel Particulate Filter (DPF)
Diesel Oxidation catalyst and particulate filter have been widely used for PM removal in diesel
applications. DOC is one of the oldest technologies originated from the early two way catalyst
for controlling CO, HC and PM. DOC works by oxidizing unburned species of fuel in the exhaust
to h armless p roduct s uch a s C O2 and H 2O. D OCs come in m etallic o r c eramic t hrough
honeycomb substrates coated with an oxidizing catalyst such as platinum, palladium or both due
to low temperature activity for HC conversions [MECA 2007]. Johnson T.V., (2010) highlighted
the usage of DOC as being used in more vehicles than any other emission control device. Their
critical p resent for t he p roper f unctioning of DPF a nd d eNOx s ystem was als o r eviewed an d
continuously evolving.
Diesel Particulate Filters (DPF) are devices which remove diesel particulate matter (PM) or soot
from the exhaust g as o f d iesel e ngines. It works by f orcing t he p articulate matter t o fl ow
through a wall fl ow ceramic h oneycomb filter. The f ilters have alternate o pen a nd c losed
channel as illustrated in figure 2.2. The exhaust gases contained PM or soot will enter the open
channel, a nd gaseous CO2 and H 2O w ill passes t hrough t he w all. D ry carbon soot particle s ize
Chapter 2 Literature Review
9
larger than the monolith wall are trapped until the pressure drop across the DPF become too
high.
Figure 2.2 Wall-Flow DPF (reproduced from Heck 2009)
However DPFs have limited capability and will eventually fully clog, therefore they need to be
periodically regenerated by c ombustion o f t he t rapped P M. T he s oot r equires a m inimum
temperature of 500OC for ignition in the absence of a catalyst which the engine exhaust does
not frequently o r reliably re ach. A dditional s teps o r m echanism are n eeded t o c lean u p t he
trapped PM, reduce the back pressure and restart the trapping cycle. (Heck 2009)
Konstandopoulos et al., (2000) suggested three method of facilitating the DPF regeneration in
order t o maintain t he s atisfactory performance of DPF. They involved a ctive, e xternal an d
passive regeneration. Th e active r egeneration i nvolved c hanging th e o peration o f th e d iesel
engine w hile p assive approach involved m odification o f t he t rap c omposition. E xternal
regeneration would be possible with the introduction of an external system to heat up the trap.
Magdi et al., (1999) evaluated the performance of DOCs and DPFs coupled with SCR system and
reported exc ellent results for P M e mission. S CR w ith D OC c an ac hieved P M e mission o f 0 .05
g/bhp-hr and combined PM, NOx and NHMC of less than 1.5 g/bhp-hr. DPF technology further
reduced the PM emissions below 0.01 g/bhp-hr. Beeck et al., (2006) reviewed possible conflict
from in tegration of S CR with DPF technologies b ased o n p ure t hermal an d c atalyzed DPF
regeneration as s hown in fig ure 2 .2a. The b enefit o f F uel B orne Catalyst ( FBC) w as al so
highlighted w hich p rovides fle xible t hermal management allo wing fas t an d c omplete DPF
regeneration.
Chapter 2 Literature Review
10
Figure 2.2a Possible architecture for NOx/PM control (Beeck et al. 2006)
Gurupatham et al., (2008) compared t he i ntegrated D OC-SCR-DPF, D OC-DPF-SCR an d c losed
couple DOC-DPF-SCR as shown in figure 2.2b. The DPF forward system shows better PM active
regeneration due to being closer to the engine and greater passive regeneration of DOC by NO2.
However, DPF forward system disadvantage includes substantially delay of hot gas downstream
reducing its SCR light off and the reduction of NO2 by SCR reactions because of soot oxidation by
NO2 in the DPF. The c lose coupled DOC-DPF improved warm up t ime of DPF and SCR for cold
start.
Figure 2.2b Schematic of an advance diesel after treatment system architecture compared in Gurupatham et al., (2008)
Guo G. et al., (2010) introduced an SCR washcoat with wall flow on DPF called SCRF together
with t raditional SCR catalyst in l ight duty d iesel application to perform NOx and PM reduction
Chapter 2 Literature Review
11
simultaneously. However low washcoat loading on SCRF due to backpressure concern, cause the
NOx reduction efficiency lower than SCRF placed upstream of SCR catalyst.
Figure 2.2c Advance diesel after treatment system with SCRF concepts (Guo et al., 2010)
Gieshoff et al., (2001) discovered that the SCR catalyst is affected by the unburned diesel fuel
therefore s uggested a DOC b e placed upstream t o r emove u nburned h ydrocarbon. Koebel
(2002) and Koebel (2001) also highlighted an increased NO2 level can be realized by placing an
oxidation catalyst which promotes oxidation of NO. The oxidation catalyst placed upstream of
the u rea i njection p oint decreased V 2O5 light o ff t emperature t o as lo w as 1 50OC. Th e
disadvantages of this was an increased oxidation of sulphur dioxide and sulfate PM which result
from using fuels of higher sulphur content and an increased of ammonium nitrate formation at
temperature below 200OC.
Lambert et al., (2006) proposed to m ove the SCR upstream o f t he D PF to h andle c old s tart
issues for p assenger c ar. Many a utomotive m anufacturers h ave a nnounced SCR sy stems for
their latest SUVs and LDTs with undisclosed system configuration especially regarding the actual
location of the SCR catalyst.
Chapter 2 Literature Review
12
2.2.1 Effect of NO2/NO ratio on NOx conversion.
Chandler (2000) suggested that the c omposition of exh aust g ases e mission a re m ostly of N O
(from 8 5-95%) an d s mall quantity o f N O2 (5-15%). It wa s r eported th at increasing t he N O2
fraction in t he fe ed g as c an im prove low temperature a ctivity o f th e V 2O5 as s hown in fig ure
2.2.1a
Figure 2.2.1a Effect of NO2/NO ratio on NOx conversion in V2O5/TiO2 catalyst (Chandler, 2000)
Gieshoff (2001) also reported similar performance with CU/ZSM-5 and other low temperature
zeolite based catalysts. Narayanaswamy et al., (2008) simulated NO2/NO ratios up to three and
implied good conversion over zeolite with excess NO2.
The significance of excess NO2 particularly over zeolite at lower temperature was discussed by
Rahkamaa-Tolonen et al., (2005) who stated that excess NO2 will enhance t he SCR re actions.
Takada et al., (2007) also s how go od N Ox c onversion w ith h igh N O2 level ( > 5 0%) in t heir
modelling of reactions over zeolite at a temperature range from 500 to 550 K. Devadas et al.,
(2006) also supported excess NO2 particularly over zeolite an d reported b est performance a t
NO2/NOx ratio of 75% which is much higher than the generally accepted optimum 50%.
Chapter 2 Literature Review
13
However Cooper (2003) suggested that the amount on NO2 must be optimised by suitable sizing
and formulation o f the o xidation c atalyst. I f t he NO2 level are too h igh, NOx c onversion
efficiency decreases as shown by the red dash line and circles in figure 2.2.1b
Figure 2.2.1b Effect of NO2 from DOC on NOx conversion (Cooper 2003).
Cooper (2003) also suggested a large Pt loading Oxidation catalyst to increase the NO2/NO ratio
to nearly 5 (over 80% NO2 in NOx) at around 280OC. As a result, the NOx conversion deteriorated
significantly d ue t o d epletion o f am monia s ince t he required NO w as s ubstituted b y N O2 as
shown in red line in figure 2.2.1b.
2.3 SCR Catalyst types
The formulation of catalyst is important for the SCR reaction to take place. Three SCR catalysts
commonly used are platinum, vanadium and zeolite.
2.3.1 Platinum catalysts
The historical development of the SCR technology discovered that NH3 can react selectively with
NOx to produce elemental N2 over platinum catalyst in excess oxygen [Heck 2009]. Heck (1993)
Chapter 2 Literature Review
14
suggested that the first SCR catalyst discovered was platinum but with limited usage due to low
temperature ac tivity. The effective t emperature w indow fo r p latinum w as fo und fro m 1 75 t o
250OC[DieselNet 2005]. Due to its poor activity at higher temperature, the other base metal like
vanadium and zeolite catalysts were found to be effective at higher temperature windows.
2.3.2 Vanadia Titania Catalysts
Bosch and Janssen (1988) suggested V 2O5/Al2O3 catalysts be u sed f or operating temperature
higher than 250OC but restricted to sulphur free application due to deactivation of the catalyst
from alu mina re action with S O3 forming A l2(SO4)3. T he nonsulphating T iO2 carrier w as
recommended for the V2O5. Amon and Keefe (2001) reported extensive studies of V2O5 catalyst
supported on TiO2 and WO3 added for HD diesel in Europe with numerous on highway studies.
Lambert et al., (2006) highlighted problem with vanadium catalyst which quickly deactivated at
high t emperatures a bove 6 00OC therefore s uggested z eolite c atalyst. Th e r ecommended
temperature window for vanadium is from 300 to 450OC [DieselNet 2005].
2.3.3 Zeolite Catalysts
Zeolite catalysts were developed to cover a wider range of temperature windows over platinum
and vanadium based catalysts. Byrne et al., (1992) suggested zeolite based catalyst to further
extend th e operating te mperature a bove 350OC. However t wo t ype of z eolite c atalysts were
develop t o c over h igh a nd l ow t emperature w indows. T he h igh temperature z eolite covers
temperature windows from 350 to 600OC while the low temperature zeolite covers 150 to 450OC
[DieselNet 2005]
2.3.3.1 High Temperature Zeolite
Chen (1995) identified mordenite as t he first zeolite ac tive SCR catalyst. Common mordenites
have a w ell d efined crystalline s tructure w ith SiO2: Al2O3 ratio of 10. I t w as n ot p ossible t o
describe them in details as manufacturers keep their catalyst formulation undisclosed. Typically
the zeolite catalysts are exchanged with metal and iron-exchanged zeolite were found useful in
SCR application.
Chapter 2 Literature Review
15
Heck (1994) found that zeolite can operate up to 600OC and in the presence of NOx, ammonia
was not oxidised to NOx therefore its NOx conversion continually increases with temperature.
Therefore the upper temperature l imit for this type of zeolite catalysts may be determined by
catalyst durability rather than selectivity. It was suggested that this type of zeolite catalysts may
be p rone t o s tability p roblems a t h igh te mperature wi th th e p resence of water v apour. F or
excessive temperature above 600OC in a h igh water content zeolite tends to deactivate by de-
alumination where Al+3 ion in the SiO2-Al2O3 migrated out of the structure leading to permanent
deactivation and in extreme cases collapsed the crystalline structure.
Lambert et al., (2006) suggested th e i mportance of t hermal d urability of z eolite c atalysts
particularly w ith t he in tegration w ith D PF with f orced r egeneration. Th e z eolite catalyst is
capable of withstanding temperature above 650OC and brief exposure to temperature of 750 -
850OC. Theis (2009) recommended Fe-zeolite catalyst for NOx control at high temperature from
400-600OC. Giovanni et al., (2007) found F e-zeolite have h igher N Ox c onversion a bove 350OC
with no significant N2O produced and suggested not to exceed 925OC
2.3.3.1 Low temperature Zeolite
Gieshoff (2001) and Spurk et al., (2001) suggested th at a d ifferent t ype of l ow temperature
zeolite catalyst could be developed for mobile engine application. I n the 1990s, research was
conducted f or t he f ormulation o f C u-exchanged Z SM-5 z eolite als o k nown as a lean-NOx
catalyst. The Cu/ZSM-5 was active in reducing NOx within a temperature range of 200 to 400OC
but w ith in sufficient thermal d urability. T his le d to a new f ormulation b y modifying t he i on-
exchanging of zeolite to undisclosed transition metals. The normal NOx reducing activity for this
catalyst was low and the f inal low temperature zeolite was thermally stable up to 650OC. T his
formulation has been designed specifically fo r NO2 gases w hich significantly improved it s NOx
conversion a nd e xtended the t emperature wi ndow with N Ox r eduction e fficiency b etter t han
90% over a temperature range of 150-500OC.
Theis (2009) also suggested C u-Zeolite catalysts as m ore effective f or N Ox control at lo w
temperature in the range of 200 to 400OC. Giovanni et al., (2007) again found Cu-zeolite to have
higher N Ox c onversion a t tem perature below 3 50OC w ith s ignificant N 2O p roduced a nd
suggested not to exceed 775OC
Chapter 2 Literature Review
16
2.3.4 Comparison of SCR catalysts.
The basis of SCR catalyst comparison is mainly on the operating temperature windows. Each of
the c atalysts has their o wn lim itations an d p roblems an d are continuously redeveloped for
further improvement in term of NOx conversion efficiency and thermal durability.
Schmieg et al., (2005) summarized t he p erformance c omparison o f c u-zeolite an d fe -zeolite
with v anadium b ased catalyst to provide useful gu idance i n the design an d operation o f u rea
SCR N Ox r eduction s ystems. Th e ef fect of N O: N O2 ratio on s teady s tate N Ox reduction on a
typical diesel exhaust temperature of 150 to 500OC was investigated. Transient measurements
were performed to determine the impact of NH3: NOx ratio and NH3 storage on catalyst and HC
and sulphur poisoning effect.
Hamada (2005) reported new formulations with bi-functional catalyst design to simultaneously
reduce NOx a nd o xidize t he NH3 slip as w ell as CO a nd HC. Walker (2005) compared t he SCR
catalyst temperature windows for NOx reduction with ammonia and summarized them in figure
2.3. C ontinuous e ffort on c atalyst f ormulation is p rogressing t oward wider t emperature
windows, thermal durability, NOx conversion and cost.
Figure 2.3 Comparison of SCR catalyst operating temperature windows (Walker 2005)
Chapter 2 Literature Review
17
2.4 SCR reductants
Two m ost c ommonly used S CR r eductants a re a nhydrous a mmonia and a queous a mmonia or
urea. Pure a nhydrous a mmonia i s extremely toxic a nd d ifficult t o s afely s tore, b ut n eeds n o
further c onversion t o operate w ithin an S CR. It is typically fa vored b y larg e in dustrial S CR
operators. A queous a mmonia must b e hydrolyzed in o rder to b e u sed, b ut i t i s s ubstantially
safer to store and transport than anhydrous ammonia. Urea is the safest to store, but requires
conversion t o a mmonia through t hermal d ecomposition i n order to b e u sed a s a n e ffective
reductant [DieselNet 2005].
The aqueous ammonia is also known as AdBlue, Urea Water Solution (UWS) and Diesel Exhaust
Fluid (DEF) depending on manufacturers. Eberhard (1994) introduced the use of solid urea but it
has received v ery l ittle a cceptance. Hoffman (1996) suggested an alternative t o u rea u sing
carbamate salt such as ammonium carbamate, NH2COONH4. Kelly et al., (2006) reported various
amines evaluated as SCR reductants which could potentially be generated from diesel fuel and
nitrogen.
Alkemade et al., (2006) reviewed the best reductant to be used for SCR system. While ammonia
offer slightly better performance, its toxicity and handling difficulty remain the biggest concern.
Urea is not as effective but safer to handle which has made it the popular choice for automotive
manufacturers. Sullivan et al., (2005) suggested in both form of ammonia it has to be extremely
pure d ue t o the fact th at impurities c an c log t he c atalyst. An SCR c atalyst t ypically re quires
frequent cleaning even with pure reductants as the reductants can cake the inlet surface of the
catalyst w hen the exhaust g as s tream te mperature i s to o l ow f or th e S CR r eaction to o ccur.
Research in to reductant t echnology is c ontinuing an d a w ide variety o f alternative re ductant
have been explored especially the one with wide availability and a distribution infrastructure in
place. [US EPA 2006]
2.4.1 Aqueous Ammonia
Aqueous a mmonia o r water solutions urea remained t he preferred choice for SCR application
due t o safe h andling an d commercial availability. A dBlue is a r egistered t rademark for A US32
Chapter 2 Literature Review
18
(aqueous U rea S olution 32.5% b y weight) I t i s a s olution of h igh p urity urea ( 32.5%)in
demineralised water (67.5%) used as a supplementary operating fluid (reducing agent) in diesel
powered vehicles using selective catalytic reduction (SCR) to improve exhaust emissions. AUS32
is primarily produced in Europe by BASF and AMI, however many other companies manufacture
their own similar solution in varying quantities. [BASF 2003]
AUS32 is carried onboard the vehicle in a tank separate to the fuel system and is sprayed into
the engine exhaust gases in a special catalytic converter. A typical SCR system uses an amount of
AUS32 equivalent to approximately 3 to 5% of the vehicle fuel consumption. In order to ensure
effective working o f t he SCR s ystem, c are must b e taken t o e nsure p urity of t he c atalyst an d
reducing agent. Any small contaminant can severely reduce the SCR system performance. The
manufacturing quality control for AUS32 solutions is governed by DIN standard 70070 [Focus on
Catalysts (8), 2, 2005]
SCR systems u sing A dBlue a re currently fitted to many trucks and b uses m anufactured b y
Mercedes Benz, Volvo Trucks, DAF Trucks and Iveco, however AdBlue usage as reducing agent is
hindered b y i ts r elative availability. S chemes a re u nderway i n E urope but t o l esser ex tents i n
Australasia and North America t o improve t he network d istributors fo r AdBlue and o ther SCR
additive. Internet based tool have been developed to map the locations of AUS32 filling stations
reflecting plans for small scale use of SCR system in private vehicle as well as corporate fleets
[Focus on Catalysts(2), 3, 2006].
The t ypical aq ueous u rea s olutions fo r S CR system concentration at 3 2.5% fo rm an e utectic
solution c haracterized b y t he lo west c rystallization p oint o f -11OC. Th e eu tectic s olution i s
advantages d ue t o e qual concentrations in liq uid an d s olid p hases d uring c rystallization. W ith
even p artial f reezing of the s olution in t he u rea t anks, c rystallization would not change t he
concentration of the urea solution fed to the SCR system [BASF 2003].
Chapter 2 Literature Review
19
Figure 2.4.1a Urea solution freezing point [BASF 2003].
The 32.5% urea solution is a colourless liquid with a faint alkaline reaction. The freshly prepared
solutions have a pH of 9 to 9 .5. In solution the urea decomposes s lowly in room temperature
into am monia an d CO2. When th e s olution i s h eated, th e rate of d ecomposition in creases
additionally producing biuret [BASF 2003].
Figure 2.4.1b Urea solution 32.5% decomposition [BASF 2003].
Fang and DaCosta (2003) highlighted possible side reactions from decomposition of urea in HDD
application. Koebel et al., (2000) also presented problem related to urea during start up due to
its freezing point at -11OC which cause it to be heated if the surrounding temperature is lower.
Chapter 2 Literature Review
20
Problem associated with urea spray have triggered for alternative solution to supply ammonia
gas to the SCR system. Elmoe et al., (2006) suggested solid ammonia storage using Mg (NH3)6Cl2
which has high ammonia density very close to urea solution. Taturr et al., (2009) also provide
alternative to urea with the use of ammonium carbamate [(NH2-CO2)-(NH4)] in HD diesel which
is capable to supply ammonia by heating at a c apacity 3 to 4 times more than urea. Therefore,
other alternatives than urea to supply ammonia to the SCR system are continuously explored.
2.4.2 Anhydrous ammonia.
The term anhydrous ammonia refers to the absence of water in the material. Ammonia gas is a
compound consisting of nitrogen and hydrogen, NH3. It is a colourless gas with pungent odour.
Ammonia is widely used in agricultures and contributes significantly to the nutritional needs of
terrestrial organisms as by serving as food and fertilizer. The liquid boiling temperature is at -
33.34OC and it solidifies at -77.7OC to w hite c rystals therefore the m ust be s tored under h igh
pressure or low temperature [BOC datasheet 2005].
Although w idely u sed, ammonia g as is c lassified as toxic an d d angerous for t he e nvironment.
The US EPA has established a guideline for Permissible exposure level (PEL) of 50 ppm in an 8
hours w eighted av erage. Anhydrous am monia also corrodes copper an d z inc containing allo y,
therefore brass fittings must be avoided in handling the gas and liquid ammonia can also attack
rubber and certain plastics [Yost D.M., 2007]
Recent d evelopment in S CR t echnology c onsiders r eadily av ailable a mmonia gas rat her t han
aqueous ammonia solution. Ammonia in g as fo rm can b e s upplied u sing a special s torage
container or specially design ammonia storage system.
2.5 Challenges in automotive SCR.
Johnson T.V. (2010) reviewed various research efforts in o ptimizing t he S CR s ystem a nd
highlighted D PF p lacement w ith re gards to S CR, n on u rea a mmonia s ystems, m ixed z eolite
catalyst development and f undamental u nderstanding o n i ssues s uch a s ammonia s torage,
sulphur i mpact and reaction m echanism. D evelopment o n LNT-SCR s ystem where th e L NT i s
Chapter 2 Literature Review
21
calibrated t o g enerate a mmonia f or t he S CR w as als o discussed. Despite p romising N Ox
conversion with the SCR system, many other grey areas need attention to further improve the
system.
2.5.1 Ammonia slip
Ammonia slip re mains the u ndesired e mission in th e S CR s ystem. It c an b e described as
ammonia that exits the SCR system unreacted. Huennekes et al., (2006) suggested 3 ways the
injected urea can le ad to NH3 slipping o ut o f t he SCR catalyst. I t involved t he incomplete SCR
reaction d ue to NH3: NOx ratio h igher t han N Ox conversion e fficiency, t he re leased o f s tored
ammonia from SCR catalyst and the incomplete decomposition of urea before reaching the SCR
catalyst. Girard et al., (2007) also reported NH3 slippage as a result of high NH3: NOx ratio (called
alpha). It was suggested reducing the alpha value less than one at low temperature where the
ideal alpha is equal to one.
2.5.2 Uniform mixing of Urea.
The urea injection quality and mixing are complex and critically important. In real engine testing
such as in this study, uncertainties existed over the uniform mixing of the urea spray with the
exhaust gases. Gorbach et al., (2009) introduced urea mixers for mixing of urea droplets from
sprays and saw s ystem efficiencies v ary fr om 60 t o 9 5% d epending o n a mmonia d istribution
across the catalyst. The urea mixer comes in a variety of types ranging from wire mesh designs
to vanes and honeycomb. Breedlove et al., (2008) suggested the use of different nozzle designs
to provide different droplet quality with range of characteristics at different injection stages.
2.5.3 Spray effect on temperature
Johannessen et al., (2008) reported that th e s prayed u rea i n exhaust s tream reduced the
exhaust g as te mperature b y 1 0-15OC t herefore d iminished t he N Ox c onversion e fficiency
especially in the low temperature region. Way (2008) also reported problem with urea injection
Chapter 2 Literature Review
22
at low temperature ( less than 190OC) where incomplete evaporation of urea and solid deposit
build-up occurred in the exhaust system.
2.5.4 Space velocity
Koebel et al., (2001) described problem faced by the SCR system in automotive application due
to low exhaust gas temperature and short resident time due to space constraints in LD Diesel
application. T he p roblem le ads t o t he re duced p erformance o f S CR s ystems re sulting fro m
incomplete thermolysis of urea before entering the SCR catalyst. It is reported that only 50% of
urea decomposed at 400O C and even lower than 15% at 255O C.
2.5.5 Light duty diesel engine study
Fisher et al., (2004) reported s uccessful a daptation o f t he S CR s ystem b y European t ruck
manufacturers to comply with Euro 4 and 5 standards. Beeck et al., (2006) suggested that the
urea SCR system integration seems quite easy on HDD application but it is much more difficult
with the confine space in LDD such as passenger cars. Many researchers have focussed on real
engine tests with HDD application and the light duty engine test is progressing slowly. Spurk et
al., (2007) highlighted cold s tart p roblem w ith p assenger c ars and s uggested f ormulation o f
dedicated low temperature active SCR catalysts. It was suggested that the SCR catalyst need to
show wider o perating w indows. H owever the S CR system c omplexity in lig ht duty re mained
disadvantages and need further optimization.
2.5.6 SCR modelling
A lit erature r eview was undertaken an d c ompiled as p art o f an in ternal report ( private
communication, Dr C . A . Roberts (2 009). The o bjective i s to validate th e CFD model ag ainst
engine data from this study. The earlier kinetic scheme reviewed was a very simple scheme of
Chapter 2 Literature Review
23
Snyder and Subramaniam (1998). Chatterjee et al., (2005), Tronconi et al., (2005) and Chi et
al., (2005) later derived other kinetic schemes.
Chatterjee et al., (2005) comment o n t he lim itations o f s implified s urface r eaction m odels,
especially in the case of extruded catalysts; however, it was stated that their model accounts for
intra-porous diffusion and was appropriate for coated as well as extruded catalysts. Their initial
reactor experiments for intrinsic chemistry were carried out over the temperature range of 150
to 4 50 OC. T his s cheme g ives a re action rat e f or o nly t he s tandard S CR re action and b ecome
obsolete due to more complete scheme that follows.
Tranconi et al., (2005) presented a kinetic an alysis of t he s tandard S CR r eaction and f urther
extended it to ga in more f undamental i nsight i nto t he c atalytic k inetics a nd m echanism
prevailing in t he lo w t emperature re gion. T his w ould b e in teresting e specially fo r mobile
applications. I n p articular transient re active e xperiments h ave shown th at a d ecrease o f th e
ammonia ga s phase concentration t emporarily e nhanced t he NO c onversion. T hey also
suggested a n inhibiting e ffect of am monia t hat c ould p lay a n on-negligible r ole in t he S CR
reaction.
The s chemed b y Chi et al., (2005) also p rovided fu ll SCR re actions with c onstants similar t o
Tronconi e t al. scheme b ut in cludes m ore r eactions. O ne o f the main s ignificant d ifferences
between th e t wo s chemes wa s i n th e s tandard S CR r eaction r ate. The Chi e t al. s cheme
suggested th at th e rate i s d irectly p roportional t o t he am monia c oncentration w hich t his
dependent does not present in the Tranconi et al. scheme.
A vanadium scheme due to Chi et al., (2005) has been used with significant differences between
this scheme and a new scheme for Zeolite catalyst published by Chatterjee et al., (2007). The
zoelite s cheme d oes n ot include t he s low S CR r eaction b ut d oes i nclude a n N O o xidation
reaction. T he c omparison on both s chemes s hows Zeolite possessing s lightly h igher v alues o n
Ammonia ad sorption, A mmonia d esorption, A mmonia O xidation an d S tandard S CR re action.
There are significant differences on the fast SCR rate between the two schemes which suggest
that the rate calculated using the information from Chi et al., may be not accurate.
Chapter 2 Literature Review
24
Finally the scheme Olsson et al., (2008) which considers Cu-Zeolite and emphasis on ammonia
adsorption and desorption, NH3 oxidation, NO oxidation, standard SCR, rapid SCR, NO2 SCR and
N2O formation. Good agreement was obtained using this scheme therefore this zeolite scheme
remained to be used for the SCR CFD model in this study (Tamaldin et al. 2010).
To this e nd a p rogramme h as b een i nitiated with AEARG t o p rovide a s imulation t ool t hat
describes t he behaviour of a S CR system for light-duty a pplication using zeolite catalysts. T his
thesis describes an engine test bed programme designed to provide data for model validation.
Chapter 3 describe development of the test rig.
Chapter 3 Research Methodology
25
CHAPTER 3: RESEARCH METHODOLOGY
3.0 Introduction
The details of the engine commissioning and experimental procedures for the steady state tests are
given in this chapter. This includes the engine, exhaust and analysers’ preparation, the technical
aspect, measurement and calibration of the equipment. The urea SCR spray system and the
ammonia gas injection system will also be covered along with the calibration charts required. Several
precautions and cleaning procedure will also be included especially for the urea SCR spray system.
The final assembly of the SCR exhaust system will be covered and also the final experimental matrix
for measuring the exhaust gases upstream and downstream of the SCR brick.
3.1 Engine Commissioning and Setup
The original plan was to use a Ford 4FM series diesel engine with a new transient engine test bed.
Some time was spent to commission this engine with a new transient engine dynamometer within
the university. Due to various problems with commissioning the 4FM series involving ECU (Engine
Control Unit), wiring harness and diesel injectors, a 2FM series diesel engine used during recent Lean
NOx Trap (LNT) studies was configured to run steady state tests for this investigation on a EC (Eddy
Current) dynamometer
3.1.1 Engine Commissioning and Setup for Steady State Test.
The recent Lean NOx Trap project within AEARG (Automotive Engineering Applied Research Group)
Coventry University used a 2FM series diesel engine equipped with VGT and EGR, an Injection
Control Unit (ICU) and an Engine Control Unit (ECU). This engine is also equipped with common rail
injection system with a high pressure fuel pump, an intercooler and an engine management system
(EMS) programmed though dSPACE, GREDI and a throttle body to control the intake air to the
engine. The throttle body was controlled by dSPACE using a customized application based on Matlab
Simulink. The application software was capable of controlling the timing for main, pilot and post
injection and also controlling the opening and closing of the throttle body. GREDI was the
monitoring software which reads the ECU and displays the value of parameters needed on a host
computer. Any parameter changed through dSPACE was recorded in GREDI alongside with the
Froude Consine test bed host computer. All the software and hardware was supplied by Ford
Chapter 3 Research Methodology
26
including the license for dSPACE, GREDI and Matlab Simulink. At a later stage of this project the EMS
capability from dSPACE and GREDI was disabled due to technical failure of the ECU. Another ECU
was programmed for this 2FM series diesel engine and the previous control of the throttle body for
regeneration purpose was disabled. Therefore this project focussed only on steady state testing
using pre-programmed engine settings. The exhaust back pressure was also monitored as an
indicator for the DPF cleaning process. The 2FM configuration is shown in figure 3.1.1
Figure 3.1.1 The 2FM Series Engine with Injection Control Unit (ICU)
and Engine Control Unit (ECU) on Froude Consine AG150 engine dynamometer.
The specification of the diesel engines is shown in table 3.1.1 and the power curve for this engine is
supplied in the appendix 3.1.1
Table 3.1.1 Diesel Engine specification used for investigation (Ford 2FM series)
Items Description Engine capacity 1998 cc / 121.9 cu in
Bore 86.0 mm / 3.39 in
Stroke 86.0 mm / 3.39 in
Compression ratio 18.2:1
Number of cylinders Inline 4, 16 valves
Firing order 1-3-4-2 Rated power output 96.9 kW / 130.0 bhp at 3800 rpm
Rated torque 330 Nm /243.4 ft lbs at 1800 rpm Ignition type Common rail, diesel fuelled, direct injection system
ICU
ECU
Chapter 3 Research Methodology
27
3.1.2 Engine Dynamometer
The engine dynamometer was an Eddy Current (EC) AG150 from Froude Consine rated at 150 kW
(200 BHP) and 500 Nm (370 lb-ft) torque with maximum speed of 8000 rpm. The AG series is also
known as the air gap range of eddy current dynamometers which has been designed to be compact,
robust and allow easy maintenance. The dynamometer is fitted with oil injected half couplings at
either end of a non-magnetic stainless steel shaft which is supported in grease lubricated, deep
groove ball bearings.
The dynamometer casing houses twin magnetising coils that produce a retarding controllable
magnetic field that resists the applied torque. Heat generated in this process is dissipated by cooling
water. Rotation of the casing is resisted by a precision strain gauge load cell that gives accurate
measurement of total input torque, measurement accuracy of ±0.25% of full rated torque and a
speed measurement accuracy of ±1 RPM. The dynamometer has low inertia, bi-directional motion
and high reliability.
3.1.3 Engine mass flow rate measurement
The engine mass flow rate was measured using a Ricardo mass flow meter coupled with a digital
manometer. Prior to testing the flow meter was calibrated in the flow lab within the university. The
Ricardo mass flow meter was connected to a pre-calibrated nozzle on an air flow rig (figure 3.1.3). A
digital manometer was connected to the Ricardo mass flow meter and the air flow supply was
varied. The air pressure drop was recorded for every air flow rate supplied and a calibration chart
was produced for use on the engine. The arrangement used for air flow meter calibration is shown in
figure 3.1.3 and the calibration chart is shown in Appendix 3.1.3.
.
Figure 3.1.3 Ricardo mass flow meter calibration [Courtesy of S. Quadri]
Chapter 3 Research Methodology
28
On the engine the mass flow rate was measured with a Testo digital manometer in mmH20 and later
converted to gram/seconds and was recorded throughout the investigation. The Ricardo mass flow
meter configuration with digital manometer is shown in figure 3.1.4
Figure 3.1.4 Ricardo mass flow meter measuring engine Mass Flow Rate (MFR)
3.2 Final SCR Exhaust build and commissioning.
The Selective Catalyst Reduction (SCR) exhaust system was built based on the parts supplied by
EMCON Technologies Incorporated and catalysts supplied by Johnson Matthey and the finalized
drawing agreed in a quarterly review meeting at Coventry University. The details of the parts
supplied are listed in appendix 3.2. The SCR exhaust system comprises a Diesel Particulate Filter
(DPF), Diesel Oxidation Catalyst (DOC), expansion chamber and nozzle, a narrow angled diffuser, SCR
catalyst, bypass pipe and instrumentation modules. Figure 3.2 shows a schematic of the final
assembly. It has been designed in such a way so to provide approximately 1D flow for comparison
with a 1D computational model. Details of the components are discussed later.
From the engine exhaust manifold outlet, the exhaust was connected to the Diesel Oxidation
Catalyst (DOC) for NO, CO and HC oxidation. Diesel oxidation catalysts can reduce emissions of
particulate matter (PM) from 15 to 30 percent while hydrocarbons (HC) and carbon monoxide (CO)
by over 90 percent within temperature interval of 20 to 30 0C(45).These processes can be described
by the following chemical reactions.
Digital manometers
Ricardo mass flow meter
Chapter 3 Research Methodology
29
[HC] + O2 CO2 + H2O Equation 3.2a
CO + 1/2O2 CO2 Equation 3.2b
HC are oxidized to form carbon dioxide and water vapour. The reaction in equation 3.2a represents
two processes: the oxidation of gas phase HC and the oxidation of organic fraction of diesel
particulates (SOF) compounds. Reaction in equation 3.2b describes the oxidation of carbon
monoxide to carbon dioxide. Since carbon dioxide and water vapour are considered harmless, the
above reactions bring an obvious emission benefit. The most significant contribution of the DOC is to
oxidize incoming NO to NO2 which allow fast SCR reaction to reduce NOx as described in the
equation 3.2c
2NH3 + NO + NO2 2N2 + 3H2O Equation 3.2c
Therefore, the arrangement where DPF and DOC were designed in this investigation was crucial to
provide sufficient NO/NO2 ratio for optimum SCR reaction. The first instrumentation module was
connected to the DOC to accommodate the EXSA, MEXA analyser, lambda sensor and
thermocouples for measuring the exhaust emissions downstream of the DPF and DOC and also
monitoring exhaust temperature.
Figure 3.2 Final Assembly of the SCR Exhaust System.
Bypass pipe
DOC DPF
Chapter 3 Research Methodology
30
3.2.1 SCR Exhaust Fabrications and Specifications.
The SCR exhaust fabrication took place at various facilities across the university, the local fabrication
workshop at the university and also at the collaborating companies facilities of EMCON Technology
and Johnson Matthey.
Figure 3.2.1 The suspended exhaust from a square metal frame.
The complete SCR exhaust system was suspended horizontally from a metal square frame with cable
wire as shown in figure 3.2.1. Sealing gaskets were placed in between each component. The gasket
used was a high temperature resistance type in order to prevent gas leakage from the exhaust
system. Some minor adjustment was necessary in the final SCR exhaust assembly because of the
restricted space within the cell.
3.2.2 DPF-DOC assembly.
The first component of the exhaust system comprises of DPF coupled with DOC. In the initial plan
the DPF and DOC were to be connected in a vertical position but they were later repositioned due to
cell constraints and laid horizontally as in figure 3.2. A final assembly front view and isometric view
drawing is shown in appendix 3.2b. A draining plug was fitted underneath the expansion box which
houses the spray assembly. Two DOC configurations were available for this investigation; a single
DOC of diameter 115 mm and length 95 mm and a double DOC of the same diameter but of length
190 mm. This is shown in the DOC assembly drawing in appendix 3.2b.The details of DPF assembly
are also shown in the DPF assembly drawing of appendix 3.2b. The detail specification of the DOC is
shown in table 3.2.2.
Chapter 3 Research Methodology
31
Table 3.2.2 Detail specification of the DOC catalyst
Diameter 118.4 mm with 115 mm exposed in rig
Length Single = 91 mm, Volume approximately 1 litre
Double = 182 mm, Volume approximately 2 litre
Cell Density 400 cpsi
Cell Pitch 1.27 mm
Substrate NGK HoneyCeram
Wall Thickness 0.11 mm [4.3 thou(UK),4.3 mil (USA)]
Open frontal area (non-washcoated) 83.4%
Bulk density of substrate 0.29 g/cc (290 kg/m3)
Washcoat thickness 0.085 mm
Washcoated channel dimension 1.076 mm
Washcoat loading (assuming
washcoat density = 1350 kg/m3) 158.7 kg/m3
3.2.3 SCR Catalysts Assembly
The SCR catalyst assembly has been designed to accommodate four SCR configurations in this
investigation. An assembly consisting of a single brick measuring 115 mm in diameter and of length
92.5 mm was available. Two double bricks of diameter 115 mm and length 185 mm were also
available. A blank SCR with the same dimension as the single and double bricks configurations was
also used. This SCR assembly is shown in appendix 3.2b. The single SCR can, two double SCR cans and
the blank SCR can allowed single, double, triple and quadruple SCR configurations to be tested. The
detailed specification of the SCR catalyst is shown in table 3.2.3.
Chapter 3 Research Methodology
32
Table 3.2.3 Detail specification of the SCR catalyst
Diameter 118.4 mm with 115 mm exposed in rig
Length Single = 91 mm, Volume approximately 1 litre
Double = 182 mm, Volume approximately 2 litres
Triple = 273 mm, Volume approximately 3 litres
Quadruple = 364 mm, Volume approximately 4 litres
Cell Density 400 cpsi
Cell Pitch 1.27 mm
Substrate NGK HoneyCeram
Wall Thickness 0.11 mm [4.3 thou(UK),4.3 mil (USA)]
Open frontal area (non-washcoated) 83.4%
Bulk density of substrate 0.29 g/cc (290 kg/m3)
Washcoat thickness 0.089 mm
Washcoated channel dimension 1.072 mm
Washcoat loading (assuming
washcoat density = 1350 kg/m3) 166.6 kg/m3
3.2.4 Urea Spray Mixing Chamber.
The Urea spray mixing chamber consists of a combination of a short 50 mm pipe and a 200 mm
diameter by 200 mm long plenum, attached to a bell shaped converging nozzle as shown in figure
3.2.4. The urea spray mixing chamber was designed to allow uniform mixing of urea droplets in the
presence of hot exhaust flow from the engine.
Figure 3.2.4 The Urea spray mixing chamber.
Chapter 3 Research Methodology
33
The mixing chamber has a urea spray boss fitted on top and a tiny drainage plug at the bottom. In
the event of running the test with urea spray, the chamber would house the spray injector unit while
with the NH3 gas test the boss was plugged to prevent gas leakage.
3.2.5 Instrumentation module assembly.
Four instrumentation modules were fabricated and assembled. Two of the modules were of
diameter 115mm and of length 110 mm. A third had a diameter of 115 mm and was 90 mm long
and a fourth had a diameter of 50 mm was of length 200 mm. The modules were used to house the
analysers, thermocouples and lambda sensors. The two 110mm long modules were placed after the
DPF-DOC assembly and before the SCR assembly and the 90 mm long module was placed after the
SCR assembly. The 50 mm by 200 mm pipe was placed after the mixing chamber before the long
diffuser. This pipe provided an alternative placement for Urea spray Injector. The instrumentation
modules arrangement is as shown in figure 3.2.5.
Figure 3.2.5 Instrumentation modules location along the SCR exhaust system.
Bosses were fabricated to accommodate the urea spray system, lambda sensors, analysers,
thermocouples and pressure sensors in the instrumentation modules, urea expansion box and the
end of the exhaust system. 1/8 inch BSP fittings were used for thermocouples and ¼ inch NPT
fittings for the Horiba analysers. These ports could be capped during the engine calibration process.
Cleaning of the bosses was required after assembly using respective thread taps. This was done to
remove any welding residue left on the bosses to ensure proper fitting for the instrumentation.
Chapter 3 Research Methodology
34
3.2.6 Long and short diffuser assembly
Four cones were used with different length and cone angles. The longest cone was 410 mm long
with a half cone angle of 4.5O while the shortest cone was 90 mm long with a half cone angle of
19.9O. The inlet and exit cones both were 150 mm long with half cone angles of 12.2O. The most
important cone in this assembly was the long diffuser cone. This cone was placed after the spray
assembly and before the SCR assembly. This was designed to provide an approximate uniform one
dimensional flow from the nozzle to the front face of the SCR catalyst.
3.2.7 Bypass pipe assembly.
The system was designed to have the option of a bypass system, but it was not used in the
experiments described in this thesis so the pipes were capped. Pressure tapping was installed at the
cap for measuring the exhaust backpressure for the system. The bypass T-joint with pressure tapping
is shown in figure 3.2.7.
Figure 3.2.7 Capped T-joint with pressure tapping.
3.2.8 DPF Monitoring and Preconditioning
The DOC, DPF and SCR catalysts were supplied by Johnson Matthey along with technical data and
procedure for monitoring and preconditioning. As the engine ran an increase in backpressure
indicated that the DPF was being loaded with soot. Hence during the project the DPF was
periodically cleared by blowing it out using a high pressure air supply. With a DPF system, it is
important to avoid uncontrolled regeneration especially under severe conditions such when the
engine load is rapidly reduced. This could result in damage to the DPF due to overheating especially
when there the DPF is heavily loaded with soot. Throughout the experiment, close monitoring of the
temperature and pressure across the SCR exhaust was undertaken using the thermocouples placed
at various locations across the exhaust. Monitoring and data logging was done using the Froude
Consine Texcel v10 software.
Chapter 3 Research Methodology
35
3.2.10 SCR Catalyst Monitoring and Preconditioning
In the beginning of this test programme, the engine was run for sometime and it is assumed that the
bricks were effectively de-greened.
3.3 EXSA 1500 NOx Analyser Setup
The EXSA 1500 NOx Analyser was supplied by Horiba Instruments limited. The operation of this
analyser is described in the operating manual and is targeted for measuring emissions from small
engines ranging from two or four stroke gasoline and also diesels. It is capable of measuring CO, CO2,
NOx, O2 and THC simultaneously. This equipment is compatible with the SAE J1088 (R) standard. The
standard is a SAE recommended practice and Test Procedure for the Measurement of Gaseous
Exhaust Emissions from Small Utility Engines. In this investigation, the EXSA 1500 NOx analyser was
used mainly to measure the engine out NOx level in the first instrumentation module as shown in
figure 3.3.2. The EXSA 1500 was also used to measure NO in other locations of the SCR exhaust
system based on the test matrix.
3.3.1 EXSA 1500 Specifications and Resolutions
The EXSA 1500 utilizes a cross flow type Non Dispersive Infra Red (NDIR) sensor at normal
temperature for measuring CO and CO2. For measurement of NO and NOx, a chemiluminescence
detector (CLD) is used while O2 is measured with a single coil type magnetic pressure. THC on the
other hand is measured using a heating type Flame Ionization Detector (FID). The specification of
EXSA 1500 is given in the table 3.3.1.
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36
Table 3.3.1 Technical Specifications of EXSA 1500 Common gas analyser.
[Extracted from the Horiba Ltd, EXSA 1500 operating manual Oct 2004]
Detection Target: Gasoline engine (2-stroke, 4-stroke) exhaust, GM diesel engine
exhaust gas
Detection: CO/CO2 :NDIR - Non Dispersive Infra Red Detector
NO/ NOx :CLD - Chemiluminescence Detector
O2 :MPD – Magnetic Pressure Detector
THC :HFID - Heated Flame Ionization Detector
Measurable Ranges Used CO: 0~5000ppm
CO2: 0~20 % vol.
THC: 0~500 ppm C
NOx: 0~1000 ppm
O2: 0~25 % vol.
AFR: 10-20
λ : 0.5 – 2.5
Repeatability: ±1 % of Full Scale
90% percent respond: 15 seconds
3.3.2 Gas requirements and Calibration Gases
A total of six gases and compressed air at a pressure of approximately 1.2 bars are required for the
operation and calibration of EXSA 1500 analyser. The gases are NO/NOx, CO/CO2, O2, N2, H2/He and
Air mix. The EXSA 1500 NOx analyser gas piping configuration is shown in figure 3.3.2
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Figure 3.3.2 EXSA 1500 NOx analyser gas piping configuration.
3.3.3 NOx measurement procedure
Once all the gas network connections had been made, the gas bottles were opened and maintained
at a pressure of 1.2 bars. After the EXSA 1500 analyser had been switched on and warmed up, the
calibration was completed. The hot hose temperature must reach around 191OC before the
calibration can be done. The Ozone Generator Unit (OGU) must be switched on when the NOx
analyser is used. The FUEL switch must be set to “MANU” position to ignite the FID from the EXSA
NOx
Heating Filter
Span/Cal
CO/CO2/N
EXSA-1500
Analyser
Engine SCR Exhaust System
Sampling Line
O2
N2
H2/He/
Air BTCA74
Span gas
Froude
Test bed
Compressed air outlet
@ 1.2 bar (purge)
Span gas
Zero/Cal
Zero/Cal
Zero/Cal
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38
main console. The ignite button needs to be pressed and it is necessary to wait until the alarm light
from the display goes out. Then, the FUEL switch must be switched to AUTO after the ignition had
completed. The appropriate CO, CO2, NOx, THC, O2 range must be selected. In this investigation, the
NOx range was selected from 0 to 1000 ppm and the O2 range from 0 to 20%. The rest of the species
were not needed for this investigation but are recorded as reference values.
The hot line was connected to the heating filter before reaching the exhaust sampling location.
The sampling line was 40 mm in diameter and had a maximum sampling flow rate of 3 litres per
minute. The recommended sampling line length was 6 meters but in the setup used here a 12 meter
long sampling line was used. Therefore a heating filter unit was used to ensure the sampling line was
maintained at 191OC throughout the experiment. The response time for this equipment was rated
around 23 seconds for a standard 6 meters long sampling line. [EXSA 1500 Operating manual
version Oct. 2004]
The engine also needed a warm up time. It took the engine approximately 45 to 60 minutes to fully
warm up until the last instrumentation module toward the end of exhaust reached 300OC. Once the
analyser was fully warmed up, calibrated and the engine warm up was completed, the analyser was
put on to measure and the data logged either from the Froude Texcel main logger or within the built
in data logger in the EXSA main unit. Throughout the investigation, the Froude Texcel data logger
was used as the main data logger for synchronization with the MEXA. The temperatures, lambda
sensors, spray or gas trigger and engine condition (Speed and BMEP) were also recorded by the
Froude Texcel data logger.
In most of the cases, the EXSA 1500 sampling point remained on the first instrument module where
the exhaust had passed the DPF and DOC before entering the mixing chamber where the urea spray
or gas was injected. The EXSA 1500’s capability of measuring NO and NOx also allowed it to be used
as a backup for the MEXA analyser for measuring NO and NO2. Once the NO and NOx were
measured the NO2 value could be deduced from both readings.
3.4 Ammonia analyser MEXA 1170Nx
The Horiba MEXA-1170Nx is one of the instruments capable of measuring ammonia and NOx
simultaneously as described in the operating manual [MEXA 1170Nx user manual, 2006]. This
instrument uses dual Chemiluminescence detectors (CLD) and an oxidation catalyst to measure
Chapter 3 Research Methodology
39
ammonia. Optionally, this product can measure NOx and NO2 simultaneously with a simple setting
change from the front control panel. The MEXA-1170NX main unit, which consists of an analyser
unit, houses the CLD detectors, a control unit and a vacuum pump unit (VPU) is shown in figure 3.4
Figure 3.4 The MEXA-1170Nx NH3 Analyser Unit
As compared to the EXSA, the MEXA sampling line used 60 mm diameter tubing and the maximum
sampling rate was at 5 litres per minute. The effective sampling rate was slightly lower at around 3
litres per minute due to the filter assembly being placed upstream of the analyser. The filters protect
the analyser from any unwanted HC soot entering the system. The response time for the MEXA was
stated as being around a maximum of 1.5 seconds.
3.4.1 MEXA1170Nx Specification and Resolution.
The MEXA-1170NX analyser is claimed to be capable of measuring NH3 in real time with high
sensitivity using twin CLD detectors with an NH3 oxidizing oven. In theory, by means of two heated-
type Chemiluminescence (CLD) detectors with an NH3 oxidizing oven, either NH3 or NO2 can be
measured with high sensitivity in real time by calculation of the difference of NO readings from two
detectors (one without a converter). It also features the capability of measuring NH3 and NOx, or
(optionally) NO2, NO and NOx, and should be suitable for the experiment as it can take direct
exhaust measurement without having a cooling unit and water removal. The analyser performance
and resolution is shown in section d of appendix 3.4.1 while section a through c describes its
physical, accessories and configurations. The commissioning was performed by Horiba at the AEARG,
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Coventry University site. Compressed air regulators were also installed next to the HBF-722H heating
filter inside the test cell for purging the analyser.
3.4.2 MEXA 1170Nx Gas Requirements and Calibration.
The various gases needed to operate the MEXA-1170Nx are shown in table3.4.2 below.
Table 3.4.2 Gas Requirement for MEXA-1170 NX Analyser.
Name Specification Supply pressure Note
Zero gas Nitrogen 100 % 100 kPa ± 10 kPa At calibration 3 L / min
Span gas NO in Balance N2
900 ppm
100 kPa ± 10 kPa
200 bar
At calibration 3 L / min
NH3 gas Ammonia in balance N2
95 ppm
100 kPa ± 10 kPa
200 bar
At oxidation catalyst check;
3 L / min
Ozonator gas Oxygen 100% 100 kPa ± 10 kPa At standby 0.7 L / min
Purge gas N2 100 kPa ± 10 kPa At purge 5 L / min
Gas regulators were installed for the NO bottle (in balance N2) and the ammonia bottle (in balance
N2). Precautions were taken while installing both regulators especially for the ammonia bottle which
used a left hand thread at the regulator and bottle outlet. Compressed air was used as the purge gas
instead of N2. A dust filter and oil filter or mist catcher was installed as well. The gas piping layout is
shown in figure 3.4.2.
The calibration of the MEXA analyser was performed before and after each sampling. After
completing the calibration prior to testing, a gas bottle with 900 ppm NO was used to validate the
analyser measurement. If the calibration was successful, then the experiment proceeded. If not, the
MEXA analyser was recalibrated and validated or sent for minor service. Gas measurements are
expressed as parts per million (ppm). This unit expresses the concentration of a pollutant as the ratio
of its volume if segregated pure, to the volume of the air in which it is contained.
Chapter 3 Research Methodology
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Figure 3.4.2 Gas piping Layout for MEXA-1170Nx Ammonia analyser
The calibration gas concentration was set to one range depending on the calibration bottle supplied.
The range was set by pressing the CAL key. When the calibration process was completed, the
analyser efficiency was recorded and monitored. Typically the calibration was done before and after
every test run to monitor the integrity of the results. At any time, when the efficiency dropped less
than 80% for any of the analyser units, the results were disregarded and the supplier was contacted
to rectify the problem. The filter was also changed for every 4 hours of testing for protection of the
analyser.
A custom operational procedure and calibration were implemented for this investigation according
to the basic guidelines from Horiba. This was due to various failures faced throughout the
investigation based on the standard operation and calibration procedure. Even though the action
was considered very costly it was necessary for early detection of the failure at any stage of the
experiment. Therefore, the NH3 oxidation catalyst efficiency check was performed before and after
each test by running the calibration with an ammonia bottle. For the NO efficiency check, the
procedure was undertaken weekly according to recommendation by Horiba. A daily operation and
calibration procedure is summarized in figure 3.3.4.
O2
Heating filter Compressed air outlet
Span gas NO
NH3 gas
Zero gas
Ozonator gas
N2
MEXA-1170NX Analyser Purge gas
Froude
Test bed Engine SCR Exhaust System
Sampling Line
NH3
Wall
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Figure 3.3.4 Process Flow of MEXA-1170NX Daily Operation and Calibration.
Power up from OFF
Switch ON gases
Press STNBY
Press CAL
Press MEAS
Press Purge
Press CAL again
Switch off O2
Switch off gases
Switch off MEXA if needed
Supply O2, N2, NH3, NO and compress air
Initiate warming up, Pump unit switch ON Sampling line & NH3 cat heat up. Warm up approximately 2 hours Calibration initiated. Efficiency recorded
After engine warm up completed & sampling line placed in, ready to start experiment. Filter changed every 4 hours of testing.
After completion of an experiment
Calibration reinitiated. Verify efficiency
OGU will turn off. Now MEXA back into STANDBY mode
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3.4.3 MEXA 1170Nx Working Principles The MEXA-1170NX is the NH3 measuring unit combining NO (NOx) detector based on the
Chemiluminescence (CLD) method and the oxidation catalyst. The sample gas is divided into two
lines. One line (SUM line) would go through the catalyst inside the oxidation furnace at around 850O
C. The other line (NOx line) would skip the oxidation furnace. At the catalyst, NH3 is oxidized into
NO by the reaction as follows:
4NH3 + 5O2 ==> 4NO + 6H2O
Since the oxidation efficiency in the oxidized catalyst is not 100%, the measured value is
compensated using the confirmed oxidation efficiency value. The unit is equipped with an
adjustment function to minimize the response gap between detectors in each line that may cause
error at drastic concentration change. The analyser is capable of switching between two modes. By
default in the NO2 mode the oxidation catalyst would be turned off but optionally could be turned
on for fast switching option. The carbon converter is gradually consumed by reduction process and
requires periodic replacement.
3.4.3a Working Principle of Chemiluminescence (CLD)
The details of CLD working principles are described in the MEXA 1170Nx user manual [Horiba MEXA
1170Nx operating manual 2004]. CLD is widely used as the measurement method of NO and NOx in
exhaust gases from engines because it is highly sensitive to NO and is not easily interfered by other
components. When sample gas containing NO is mixed with ozone (O3) gas in a reactor, NO is
oxidized and is transformed to NO2 as shown in the reaction:
NO + O3 ==> NO2 + O2
Some of the formed NO2 molecules here is in excited state, which means its energy is higher than
normal. Excited NO2 molecules release excitation energy as light when returning to the ground state
following these reactions:
NO + O3 ==> NO2* + 02 NO2*:NO2 molecules in excited state
NO2* ==> NO2 + hv
This phenomenon is called Chemiluminescence, and the light intensity is directly proportional to the
quality of NO molecules before the reaction. Thus, NO concentration in the sample can be estimated
by measuring the amount of radiated light.
Chapter 3 Research Methodology
44
3.4.3b Interference of CO2 and H2O
Also noted from the MEXA 1170Nx user manual is the effect from interference of CO2 and H2O to the
measurements. Some of exited NO2 molecules lose excitation energy by collision with another
molecule before returning to the ground state by emitting light. In this case, NO2 returns to ground
state, but chemiluminescence does not occur as shown in reaction;
NO2* + M ==> NO2 + M where M: Other molecules
The probability of energy loss depends on the kind of the collision opponent, and the species and
concentrations of co-existing gas components may affect NO sensitivity of the CLD method. The
probability of energy loss by CO2 and H2O is larger than that by N2 and O2 in the components of
typical engine exhaust gas. Therefore the change of CO2 and H2O concentration in the sample tends
to cause the change of NO sensitivity. In general, to lessen the interference of CO2 and H2O inside of
a reactor is maintained to a low pressure condition.
3.4.3c Measurement of NOx
Based on the working principles of CLD described in MEXA 1170Nx user manual, it is obvious that
the NO2 originally included in a sample cannot be measured by CLD, because it does not cause
chemiluminescence. To measure the NO2, it is converted to NO using NOx converter before
measurement. This is shown in the following reactions:
NO2 + C ==> NO + CO
2NO2 + C ==> 2NO + CO2
From the above reaction, it is clearly seen that carbon (C), which is the main substance of the NOx
converted is being consumed by the reduction process. Therefore, as mention earlier, the periodic
check and replacement of the NOx converter is required.
3.4.4 NOx measurement in NH3 mode.
The MEXA1170Nx detects by using a chemiluminescence detector (CLD) which can only detect NO.
In this mode the ammonia is converted to NO as illustrated in figure 3.4.4. Therefore, the top line in
figure 3.4.4 will display SUM which is the total of all NO and converted NO from Ammonia. The
Chapter 3 Research Methodology
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second line will display only the NOx measurement and thus the last display in the analyser show the
deduced ammonia by subtraction of SUM to the NOx measurement earlier.
Figure 3.4.4 NH3 mode of MEXA-1170NX analyser
3.4.5 NO2 measurement in NO2 mode.
In the NO2 mode, the NH3 catalyst is not utilized. It can be switched off or leaving it ON for fast
switching mode. In the first line of the analyser in figure 3.4.5, the exhaust gases will passes through
the oxidation catalyst unchanged. Then, any NOx will be converted to NO before being detected by
the CLD detector. Any NO will be detected directly by the CLD. Therefore, the analyser will display
NOx in the first line. In the second line, the NOx to NO converter will be bypassed, therefore the CLD
only detect NO and displayed by the analyser. Finally, the analyser only display NO2 deduced from
NOx in the first line to the NO in the second line as shown in figure 3.4.5
NOx to NO Converter
NH3 MODE – NH3 oxidised
Oxidation Catalyst @850 C
NH3 + NO + NO2 CLD detects
NO
Convert NH3 to NOx NOx to NO
NOx to NO NOx
SUM
NH3
NOx to NO Converter
CLD detects
NO
Analyser Display
(NH3 = SUM –NOx)
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Figure 3.4.5 NO2 mode of MEXA-1170NX analyser
3.5 ETAS Lambda Meter
In this investigation, the ETAS LA4 lambda meter was use to measure O2 at any of the
instrumentation modules along the SCR exhaust system. In most cases it was used to measure O2
across the SCR catalysts. The attributes of the LA4 Lambda Meter are described in the operating
manual [ETAS LA4 User’s Guide, 2005]. The manual describes the LA4 lambda meter as a high-
precision measuring device for emission levels. It allows determining lambda values, oxygen content,
and Air/Fuel ratio, as well as the internal resistance, pump current, and heater voltage of the LSU
lambda sensor. The LA4 is designed for exhaust gas measurements on gasoline, diesel and gas
engines.
Based on the output signals from Bosch LSU broadband lambda probes, the measurement results
can be calculated either by means of an analytical method that considers fuel properties and
ambient conditions or by characteristic curves. The measured value was continuously displayed on
the built-in LCD and periodically recorded manually as required. The device conducts a self-test after
being powered on using an internal reference. An optimized heater control ensures that the sensor
quickly reaches its operating temperature while preventing overheating damages, even at highly
fluctuating exhaust gas temperatures and different supply voltages. The advantages of using this
device is that it provides a wide measurement range of lambda, oxygen content and air/fuel ratio. In
this investigation, two units of LA4 Lambda meter were used as a standalone unit but the data were
NOx to NO Converter
NO2 MODE – NH3 passes through unchanged
Oxidation
Catalyst
NH3 + NO + NO2 CLD detects
NO
NOx to NO
NO
NOx
NO2
NOx to NO Converter bypassed
CLD detects
NO
Analyser Display
(NO2 = NOx –NO)
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logged to the Froude Texcel program. The LA4 lambda meters used in the experiment are shown in
figure 3.5. The LA4 wiring configuration is shown in appendix 3.5.
Figure 3.5 ETAS LA4 Lambda meter used to measure O2 before and after the SCR catalysts
3.6 Urea Spray Setup
The spray injector unit was a prototype manufactured by Hilite International Incorporated and it is a
customized standalone unit. The spray is a heavy duty spray and the dosing of urea was done
manually by setting up the spray frequency and pulse length. The configuration of the Hilite urea
spray system is illustrated in figure 3.6. For this program, manual operation of the spray system was
considered adequate since only steady state testing was performed. The inlet pressure for this
system was fixed at 5 bars
.
Figure 3.6 Schematic of a manual Urea spray system.
Exhaust Flow
Pulse controller
Power supply
Pump
Pressure Regulator
Bleeding valve
Spray Injector
From Engine
Mixing Chamber
440 micron
filter
AdBlue Tank
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3.6.1 Urea Spray Calibration
Prior to running with AdBlue solution, the spray system was calibrated and characterised to measure
the flow rate using water. Based on the measurement obtained, a calibration chart was developed
as shown in figure 3.6.1. The chart shows the mass flow rate (mg/s) against pulse length (ms) at
frequency of 5 Hz. In this chart, the line with circles shows the data calibration with water while the
line with triangle shows the urea spray.
The differences between the two lines are due to the different of specific gravity between water and
AdBlue solution. The AdBlue, at specific gravity of 1.09 is denser than water, resulting to higher mass
flow rate. Periodically, a hydrometer was used to measure the specific gravity of the AdBlue
solution. This will ensure that the AdBlue solution does not change due to storage within the vicinity
of the test cell. Using the calibration chart gave a general idea of which pulse length in milliseconds
should be used with respect to the NOx level and engine mass flow rate produced at a specific
engine load (BMEP) and speed (RPM).
Figure 3.6.1 Calibration chart of Mass flow rate (mg/s) against
Spray Pulse length (ms) [courtesy Dr C.A. Roberts]
0
20
40
60
80
100
120
140
160
180
200
0 20 40 60 80
Mas
s flo
w ra
te, m
g/s
Pulse length, ms
Hi Lite Spray 5 Hz pulse Calibration with water
Water calibration mg/sUrea (calc. for SG 1.09) mg/s
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3.6.2 Urea Spray Pulse Length Setting Procedure
To determine a suitable spray pulse length the urea spray injector calibration chart as shown in
figure 3.6.1 was used. Starting from 28 ms pulse length, the urea mass flow rate is found around
63.2 mg/s. At engine speed of 1500 rpm and 6 bars BMEP, the exhaust mass flow rate was measured
around 28.5 grams/seconds. Using this information, the potential ammonia gas produce at this
setting was worked out to be around 695 ppm as shown in appendix 3.6.2.
Repeating this procedure for various engine speeds from 1500 to 2500 rpm and load from 2 to 8 bar
gives various exhaust mass flow rate ranging from 10 to 100 grams/seconds. As a result chart of the
estimated required urea dosage against NOx was established as shown in figure 3.6.2
Figure 3.6.2 Chart showing estimated Urea/AdBlue (g/s) required
against engine NOx out (ppm)
3.6.3 Engine NOx Out Mapping
Prior to selecting the appropriate spray dosage, the engine NOx out level mapping was also
produced. This was achieved by running the engine at different Speed (RPM) and Load/BMEP (bar).
The engine mass flow rates were recorded manually as the engine speed varied from 1500 rpm to
2500 rpm and BMEP from 2 to 8 bars. The NOx levels were measured using the MEXA 1170Nx and
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0 200 400 600 800 1000
ppm NOx
requ
ired
g/s
urea
(Ad-
blue
) spr
ay
exhaust m' 10 g/s
exhaust m' 30 g/s
exhaust m' 50 g/s
exhaust m' 100 g/s
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EXSA 1500 analysers. Figure 3.6.3a and 3.6.3b provide a general engine mapping showing the engine
NOx out and mass flow rate at various engine Speed (RPM) and load, BMEP (bar).
Figure 3.6.3a Engine NOx out based on Load BMEP (bars), Speed (RPM) and EGR ON
Figure 3.6.3b Exhaust Mass Flow (g/s) based on Load, BMEP (bars), Speed (RPM) and EGR ON.
Based on the fact that the urea spray injector was for heavy duty applications, the lowest possible
spray injector setting was utilized for this investigation. It was at 24 ms which is expected to produce
about 550 ppm ammonia gas for the SCR reaction ( refer to calculation in appendix 3.6.2 ) In order to
match the lowest urea pulse rate at 24 ms, the NOx out level must be in the range of 530 to 550
Chapter 3 Research Methodology
51
ppm. Therefore in the general NOx out mapping (figure 3.6.3a) the engine condition at 1800 rpm
and BMEP 8 bars was appropriate at that time. Due to high fuel consumption at 1800 rpm and BMEP
8 bars, the EGR feature was switched off in order to increase the NOx level produced by the engine.
The low engine speed is preferable based on lower fuel consumption which allows longer testing
period with various urea spray and ammonia gas settings. Switching off the EGR also improved the
NO-NO2 ratio as detailed in section 3.8.2.
Therefore another engine NOx out mapping was produce by running the engine at 1500 rpm with
EGR off whilst varying the load BMEP from 2 to 8 bars with exhaust mass flow rate recorded. As a
result the new engine mapping at 1500 rpm was produced as shown in figure 3.6.3c. From this
engine mapping, the desirable engine condition was chosen as 1500 rpm and BMEP 6 bars with a
mass flow rate of 28.5 g/s.
Figure 3.6.3c Exhaust Mass Flow (g/s) based on Load, BMEP (bars), Speed (RPM) and EGR OFF.
3.6.4 The Urea Spray Layout and Experimental Procedure
The urea spray pump and the pulse controller were powered by their individual power supply. The
pump feeds the AdBlue solution from the tank through the pressure regulator to the spray. The
267337
406
481 550
641
1500 rpm, 732
27.32 27.44 27.56
28.23
28.53
29.93
MFR @1500rpm30.71
25
26
27
28
29
30
310
100
200
300
400
500
600
700
800
900
2 3 4 5 6 7 8 9
mas
s flo
w (g
/s)
Nox
(pp
m)
load bmep (bar)
Engine NOx out based on increasing Load (BMEP) and Speed 1500 (RPM), EGR OFF
NOx@1500 rpm MFR@1500rpm
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52
spray pulse length was controlled using the pulse controller, from 28 ms upwards. The spray was
originally designed for heavy duty so this was the minimum working range setting in the experiment.
The spray frequency remained at 5 hertz throughout the experiment. The pulse length was increased
at 2 ms increments in the experiment. The engine and both analysers were first warmed up. Next,
analyser calibrations were completed. The engine was set at 1500 rpm and BMEP of 6 bars. Once the
exhaust temperature had stabilised at 300 0C at the last instrumentation module, then the engine
warm up stage had completed. During the engine warm up, the urea spray was checked and
calibrated outside of the exhaust. Whilst this was being undertaken, the urea injector bosses were
blanked off to avoid exhaust gas leakage.
The spray was clamped on a stand and all the piping was connected as shown in figure 3.6.4a and
the power supply and the pulse controller were switched on. Normally, the spray would not start
spraying immediately and required a few seconds. The urea AdBlue solution would start dripping
and eventually spray into the bucket. Once a uniform spraying pattern was achieved, the spray could
be plugged back in its location in the exhaust system. If the spray was clogged, then a spray cleaning
procedure would take place as described in section 3.6.5. After cleaning, the spray trial would be
repeated in the bucket to ensure that cleaning had fixed the clogging problem.
Figure 3.6.4a Urea AdBlue Injector testing prior to experimental with spray system.
Once the clogging issue had been resolved, the spray testing procedure could proceed as per the
test program. The spray unit was carefully re-assembled into the exhaust making sure that it was not
over tightened. A torque wrench was available for this procedure and a torque setting of no more
than 10 Nm was applied. This was a very important procedure as over tightening the assembly could
damage the thread causing the spray to fail. The urea AdBlue pipes line and wiring were routed clear
of the hot exhaust, see figure 3.6.4b.
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53
Figure 3.6.4b Urea Spray injector and supply pipes and wiring in place.
Once the spray injector was placed at the mixing chamber, the only indication that the spray was
working properly was by monitoring NOx level reduction. In this case, the MEXA analyser sampling
line must be placed downstream of the SCR. If the NOx level remains the same for more than one
minute then the experiment was stopped and the spray was rechecked on the stand and probably
cleaned. During the engine warm up and after the spray had been cleaned and checked on the stand
with the bucket, it was found best practice not to leave the spray injector in the exhaust without
spraying.
Figure 3.6.4c Spray Injector failure.
This was because the hot exhaust flow had a tendency to bake the urea AdBlue residue left within
the spray injector assembly causing the injector not to work properly. The best practice was found to
place the urea injector in the mixing chamber and start the experiment immediately, certainly within
five minutes of insertion. Longer waiting times before the experiments started would increase the
chances of spray failure.
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Examples of spray failure are circled in the 43rd and 105th minutes of figure 3.6.4c. In the 43rd
minutes, the spray failed to open in the first 4 minutes but later open intermittently for another 3
minutes but managed to properly open after the 7th minute. In this case, the spray was previously
stopped for about 5.48 minutes. Later in the 105th minute, the spray was previously stopped for a
period of 22 minutes. At this point, the spray totally failed to open even after running for about 5
minutes. Once all the necessary precaution and injector testing were performed, then the
experiment with the urea spray system is ready as the layout shown in figure 3.6.4d.
Figure 3.6.4d Urea spray system Experimental Layout.
3.6.5 Spray Setting and Cleaning Procedures.
Due to various problems related to the use of urea AdBlue with the spray injector, a customized
spray setting and cleaning procedures was developed. These procedures involved visual inspection
and cleaning with either warm water or ultrasonic cleaning and also drying with compressed air and
a paper towel. These procedures are described in the flow chart in figure 3.6.5a. Periodically, the
interior of the spray and the urea piping was cleaned by flushing through with warm water. This was
done by substituting the urea AdBlue solution with warm water and running the spray.
Pulse controller power supply
Injector pump power supply
Pulse Controller
Pump
Injector
Pressure Regulator
Bleeding valve
440 micron
filter
AdBlue Tank
Mixing chamber
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Figure 3.6.5a Spray Cleaning Procedures flow chart
Start Cleaning
Remove spray from exhaust
Inspect white deposit build up
Check deposit severity
Half soak with warm water
If Soft deposit
Half soak with ultrasonic
cleaning unit
If Hard deposit
Wipe clean with paper towel
Blow with Compress air
around the spray
Re-fit spray to exhaust
Re-Inspect white deposit
Finish spray setting/ Experiment Started
If clean
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3.6.6 Deposit build up on Spray
The AdBlue urea solution has a tendency to crystallize when exposed to the air. This produced a
white deposit build up around the spray and tubes. Some of this white deposit hardened if exposed
to high temperature in the exhaust stream in the range of 250O to 400OC. Under some conditions
melamine formation occurred inside the spray injector opening. Some examples of these white
deposits are shown in figure 3.6.6a and 3.6.6b. When this happened, cleaning the spray by soaking
with warm water may not be suitable and an ultrasonic cleaning unit was needed.
3.6.6a Deposit on injector sleeve
3.6.6b Deposit around injector
3.6.6c Ultrasonic cleaning
-half immerse
3.6.6d Ultrasonic cleaning full submerge
Figure 3.6.6 White deposit build up and ultrasonic cleaning
The use of the ultrasonic cleaning unit is subject to special attention in order to protect the electrical
contact point of the spray unit. The spray unit was disassembled from the main unit and the outer
cover sleeve and the removable part were submerged in the ultrasonic cleaning unit as shown in
figure 3.6.6d. The cleaning normally took approximately two minutes. If necessary, the procedure
was repeated. For the main unit with electrical parts, only the mechanical part of the spray was
submerged in the ultrasonic cleaning as shown in figure 3.6.6c and the electrical contact point
Chapter 3 Research Methodology
57
remained above the water level at all times. Once the cleaning was completed the spray unit was
dried completely using compressed air. Further inspection was needed to ensure none of the
electrical parts were exposed to water or any debris from the crystallized AdBlue solution.
Sometimes certain parts of the spray injector cleaning could be done manually using tweezers. This
procedure depends on the hardness of the deposit formed. An example in this case is shown in
figure 3.6.6e
Figure 3.6.6e Manual cleaning of injector sleeve with tweezers.
3.6.7 Cleaned Spray inspection
Final visual inspection was needed after the cleaning procedures were completed. The areas to be
inspected were the main injector sleeve, the injector opening, the supply inlet and outlet and also
the complete assembly as shown in figure 3.6.7. The cleaned sleeve is shown in figure 3.6.7a while
figure 3.6.7b shows the main injector opening. Clean inlet and outlet supply lines are shown in figure
3.6.7c. The overall inspection of the spray injector required looking for any debris around the main
assembly of the spray as shown in figure 3.6.7d.
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58
3.6.7a Cleaned sleeve 3.6.7b Main injector opening
3.6.7c Cleaned inlet supply
3.6.7d Completely assembled clean injector.
Figure 3.6.7 Final visual inspection of fully cleaned injector
Chapter 3 Research Methodology
59
3.7 NH3 Gas Experimental Setup
As a comparison with the AdBlue Urea Spray experiment, NH3 gas at 4% and 5% concentration, the
balance being N2, was used. The gas experiment was conducted in order to isolate NH3 species from
urea decomposition processes. In the urea spray experiment, it was expected that the urea droplets
would be converted to NH3 gas. The phase changed and the time taken for it to decompose in the
exhaust system before reacting with the SCR catalyst is difficult to predict. Using NH3 gas should
provide information as to SCR performance when 100 % of the urea droplet had transformed to gas
phase. When compared to the urea spray experiments it should also provide insight into droplet
behaviour.
3.7.1 NH3 Gas Supply and Nozzle Location.
Initially the test was done utilizing gas bottles containing 4% NH3, the balance being N2 gas, however
only approximately 4 to 6 hours of testing was possible. To reduce costs and extend the testing time,
a 5% NH3 gas was later introduced. The flow rate was lowered about 20% from the 4% gas in order to
get similar concentration in ppm. Gas was injected into the exhaust stream at the first
instrumentation module in the same location as the EXSA 1500 sampling point.
A nozzle with a J-shape was fabricated of internal diameter 4 mm and 6 mm outside diameter. Since
the pipe diameter of the instrumentation module was 120 mm, the nozzle was designed such that is
measured 60 mm from the wall; the centre of the pipe. The nozzle was also pointed to the direction
of the flow. Before connecting the nozzle with the NH3 gas supply, the nozzle was carefully inserted
in the instrumentation module and turned to face the mixing chamber. As the NH3 gas reached the
mixing chamber, it was expected that it would mixed uniformly with the exhaust gases. Then it
would continue flowing through the long diffusing cone, as an approximate one dimensional flow,
eventually reaching the SCR catalysts for reduction with NOx. The gas injector geometry is shown in
figure 3.7.1b
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60
Figure 3.7.1b NH3 Gas Injection Nozzle.
3.7.2 Gas flow meter and pressure gauge.
A needle valve was used to control gas flow rate into the exhaust stream and a rotameter – type
flow meter measured the rate. The reading on the flow meter was calibrated to ensure an
appropriate amount of NH3 gas was injected. There were two floats available on the flow meter, a
glass float and a stainless steel float. The glass float was more sensitive and less dense but was
limited to a maximum flow rate of 24 litres per minute. The stainless steel float was denser and
suitable for higher flow rate while capable of measuring up to a maximum of 44 litres per minute.
To establish the gas flow rate, measurements must be taken by observing the position of the centre
of the float on a graduated scale. The scale ranged from 0 to 150 mm at increments of 10 mm.
Readings were converted to flow rate using a calibration chart for air with the appropriate float as
shown in appendix 3.7a and 3.7b. Flow rate was controlled using the dial at the bottom of the flow
meter. The pressure within the line was monitored by reading the pressure gauge. The gas flow
NH3 Gas Out
Exhaust flow
60mm
1st
instrumentation
module
NH3 Gas Inlet
Chapter 3 Research Methodology
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meter readings were taken manually and the changes of flow rate were marked by pressing the
voltage signal trigger.
The voltage signal trigger was a switch wired to the Froude Texcel data logger which helps to identify
the change of gas flow rate used. Therefore any changes of NOx and NH3 levels were clearly visible
and differentiated on the Texcel control panel. Actually, the measurements with gas flow meter as
shown in figure 3.7.2 were used only as a guide. The actual NH3 mass flow was calculated from the
measured ppm and exhaust flow rate.
Figure 3.7.2 Gas flow meter reading as a guide.
3.7.3 NH3 gas experimental layout.
The 5% NH3 gas was used and connected to the exhaust stream in the 1st instrumentation module.
Stainless steel pipes were used due to the nature of NH3 which has a tendency to stick on every
surface especially on materials such as Teflon. The pressure in the line was fixed to 1 bar and a
vented safety valve was connected to the air extraction system on the roof of the engine test cell. A
pressure gauge was connected to the flow meter and the pressure recorded throughout to ensure
gas flow rate can be accurately calculated. NH3 gas setup is shown in figure 3.7.3
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Figure 3.7.3 Schematic of NH3 Gas Injection setup
Figure 3.7.3 NH3 Gas Experimental Layout
3.7.4 NH3 Gas Experimental Procedure.
The procedures followed when using gas were similar to those when using urea. With the NH3 gas,
the procedures were much simpler and cleaner but appropriate precautions were necessary
including ventilation in the engine cell. Basically, after the engine and analysers had warmed up, the
NH3 gas bottle was switched on. The pressure within the gas bottle and the pipes were adjusted to
be at approximately 1 bar. If there was any leakage in the gas piping, the pressure would drop and
required necessary action.
Safety valve
5% NH3 in N2
NH3 gas flow directions
Mixing chamber
Gas flow meter
Instrument Module
Gas Injector
Pressure gauges
EXSA Sampling line
Chapter 3 Research Methodology
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The valve was opened on the flow meter and the rate adjusted by noting the position of the glass
float. The readings based on the glass float were recorded together with the pressure gauge
readings in the pipe line. The NH3 and NOx measurements were logged within the Froude Texcel
system. The engine mass flow rate readings were also taken from the Ricardo air flow meter. Various
sampling locations were used depending on the test matrix, see later in section 3.11. Once the
experiment was completed, the air flow meter dial and the gas bottle regulator were turned off. The
engine and analysers were cooled down and turned off. Finally the results were plotted and the
recorded readings were compiled and are shown in the results section of Appendix 4.
3.8 NO/NO2 measurement for DPF-DOC arrangement.
SCR performance depends on the NO/NO2 ratio and this is determined by the DPF/DOC
arrangement. Measurements were taken upstream and downstream of the DPF/DOC components.
The NO to NO2 ratio is very important for the SCR reduction reaction due to the NO2 involvement as
one of the main reductants in the SCR reaction. Initially, as recommended by the catalyst supplier,
the DPF/DOC configuration was DOC followed by DPF. However, during the preliminary NO and NO2
ratio study, it was observed that the amount of NO2 produced was not at the appropriate level for
optimal SCR performance. So, the alternative configuration was also investigated.
3.8.1 DOC-DPF configuration.
In the early stage of this investigation, the DOC-DPF was used as the configuration upstream of the
Spray and SCR catalyst. The exhaust pipe was connected first to the DOC and then the DPF assembly.
The function of the DOC is primarily to oxidize a fraction of the engine out NO to NO2. The primary
function of the DPF is to trap soot particles and so protect the downstream components, the SCR
catalysts. The experiment was conducted at an engine condition of 1500 rpm and BMEP of 6 bars
with the EGR and VGT running as normal. The engine was warmed up as per the normal procedure
and the MEXA analyser was calibrated prior to sampling.
The EXSA NOx analyser was occasionally used to measure NO and NOx for comparison. The
sampling points were at the engine out and downstream of DOC-DPF bricks as shown in figure 3.8.1.
Before running the experiment, the DPF was taken out for cleaning with compressed air. NOx and
NO measurement were obtained upstream of the DOC at the same location. The sampling probe
was then moved to the second location downstream of the DOC-DOF assembly and NO and NO2 was
Chapter 3 Research Methodology
64
recorded. The results are as shown in table 3.8.1 for an engine conditions of 1500 rpm and 6 bars
and temperature of 350 to 420 0C.
Figure 3.8.1 Initial configuration with DOC-DPF assembly.
Based on the NOx and NO measurements, the NO2 values were deduced and NO/NO2 ratio was
established. From table 3.8.1, the NO2 level before the DOC-DPF assembly was approximately 0 %.
Downstream of the DOC-DPF assembly, only 10 % of NOx was NO2. This was considered too low for
optimal performance of the SCR. It was assumed that soot in the DPF was reducing some of the NO2
from the DOC back to NO
Sampling Location NOx
(ppm)
NO
(ppm)
NO2
(ppm)
NO2/NOx
percentage
Upstream DOC-DPF 392 392 0 0 %
Downstream DOC-DPF 415 372 43 10 %
Table 3.8.1 NO/ NO2 ratio based on DOC-DPF assembly.
3.8.2 DPF-DOC configuration.
The experiment was repeated with the DPF and DOC reversed as in figure 3.8.2. The DPF will still be
expected to protect the SCR by trapping soot.
Direction of exhaust flow
2nd Sampling Location
Engine out
Sampling
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65
Figure 3.8.2 Final DPF-DOC assembly
Using this configuration, the NO and NO2 levels were measured. The results are tabulated in table
3.8.2 and show an improved NO2 level at approximately 40%.
Table 3.8.2 NO/NO2 ratio based on DPF-DOC assembly
Sampling Location NOx
(ppm)
NO
(ppm)
NO2
(ppm)
NO2/NOx
percentage
Upstream DPF-DOC 412 404 8 1.9 %
Downstream DPF-DOC 433 255 178 40 %
Based on these results the second configuration was adopted. The NO2 to NOx ratio of about 40%
was considered more desirable for this investigation. However, in most literature reviewed a higher
ratio is recommended for good NOx conversion. Narayanaswamy et al. (2008) simulated NO/NO2
ratio up to 0.25/0.75 and implied good conversion over zeolite with excess NO2. The significance of
excess NO2 over zeolite at lower temperature was discussed by Rahkamaa-Tolonen et al. (2005) to
enhance SCR reactions. Devadas et al. (2006), Takada et al.(2007) and Chatterjee et al. (2007) all
agreed that higher NO2/NOx ratios (> 50%) give good conversion of NOx.
In order to further increase the NO2 level for this experiment, the EGR was turned off. This resulted
in higher engine out NO2 levels as shown in table 3.8.3 below. The NO2/NO ratio supplied to the SCR
system in the experiments was thus generally about 60% NO2 and 40% NO. The NO2/NO ratio from
Direction of exhaust flow Engine out
Sampling
DPF DOC
2nd Sampling Location
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66
the engine was about 20% NO2 to 80% NO. This configuration was finalized and used throughout the
investigation.
Table 3.8.3 NO/NO2 ratio based on DPF-DOC assembly with EGR off.
Sampling Location NOx
(ppm)
NO
(ppm)
NO2
(ppm)
NO2/NOx
percentage
Upstream DPF-DOC 525 420 105 20 %
Downstream DPF-DOC 530 205 325 60 %
3.9 Measurement using various sampling probe length.
Prior to designing the experimental test matrix, a brief investigation of various sampling probe
lengths was also conducted. The assumption throughout was that the flow was essentially one
dimensional within the SCR. To assess the validity of this assumption, measurements were taken
inside the exhaust pipe using 3 different lengths of sampling probes. The sampling probe was
connected directly to the end of the heated line from the MEXA 1170Nx. Based on the inside
diameter of the instrumentation module (120 mm), the centre stream was 60 mm from the pipe
wall. The three sampling probes used were at 55 mm, 25 mm and 10 mm from the wall as shown in
figures 3.9a, b and c.
Figure 3.9a Variation of sampling probe length for profile measurement
Experiments were conducted using 4% NH3 gas. The experiments were conducted at engine speed of
1500 rpm and BMEP of 6 bars. The quadruple SCR catalyst was used. Initially the NOx measurement
was taken upstream of the SCR catalyst without injecting NH3 gas. Then, the MEXA sampling probe
was moved to the location downstream of the SCR catalyst and NH3 gas was injected. The analyser
Chapter 3 Research Methodology
67
was thus placed to measure NH3 or NOx slippage after the SCR. The same procedure was used for all
probes.
Figure 3.9b Long (55 mm) sampling probe Figure 3.9c Medium (25 mm) sampling probe
The comparison of results between the medium length probe and the long probe at a setting of 100
mm of the glass float are tabulated in table 3.9.
Table 3.9 Profile Measurements inside the exhaust stream.
Date/ Probe length
SCR brick
Glass float mm
Gas Pressure
psi
NOx in upstream
SCR
NH3 in upstream
SCR
NH3 out downstream
SCR
NOx out downstream
SCR 16jun/ 55 mm 4 100 1.2 579 510 6 150
24Jun/ 25 mm 4 100 1.2 576 535 7 128
24Jun/ 25 mm 4 100 1.2 576 534 5 125
From table 3.9, NOx in and NH3 out measurement do not show much variation between long (55
mm) and medium(25 mm) sampling probe. The slight variation is due to the NH3 distribution being
non-uniform upstream and hence NOx consumption is not uniform downstream. A plot of results for
the long sampling probe measurements at various gas flow rates are shown by the blue line in figure
3.9d. The two measurements using the medium sampling probe are shown in green.
55 mm 25 mm
Chapter 3 Research Methodology
68
Figure 3.9d Check point with medium sampling probe for gas measurement.
The result shows that the medium sampling probe on the MEXA ammonia analyser was producing
similar result as the long sampling probe. So it was concluded that the sampling probe length inside
the exhaust assembly does not have much impact on the measurement of the NOx and NH3 level in
the exhaust flow. As a result of this, the experiment with the short probe (10 mm) was not
necessary for the investigation. Therefore all further measurements used the long probe.
3.10 Problems associated with the MEXA Analyser
In the early stage of the investigation, the MEXA ammonia analyser failed several times when
measuring NOx or NH3 with the presence of high ammonia concentration or urea. Five types of
failures occurred involving rubber seal disintegration, sample line blockage, NOx converter failure,
NH3 oxidation catalyst poisoning and NH3, NO2 reaction on the NOx converter.
Disintegration of the rubber seal for the NOx converter (in the SUM line of the converter) resulted in
leakage of the sampling gas flow from the sampling line to the converter unit. This was detected
during NOx calibration when measuring lower NOx readings from the NOx calibration bottle.
Replacing the rubber seal required a minor service to be performed on the analyzer. A sample of the
rubber seal failure is shown in figure 3.10.1a. At this point, the damaged rubber seal was replaced
4 SCR brick with gas (4%)16 & 24 Jun 08
624, 49
302, 352
212, 432
116, 510
80, 550
NH3 in 510, NH3 out 6
NH3 in 510, NOx out150
380, 280
46, 570
0, 578
NH3 in 535, NH3 out 7
NH3 in 534, NH3 out 5
NH3 in 535, NOx out 128
NH3 in 534, NOx out 125
0
100
200
300
400
500
600
0 50 100 150 200 250 300 350 400 450 500 550 600 650 700
NH3 in
Nox
/ N
H3
out
NH3 out16/6 4SCR
NOx out16/6 4SCR
NH3 out24/6 4SCR
NOx out24/6 4SCR
Note:16 jun 08with longprobe 55mm
24 jun 08with medium probe 25mm
Chapter 3 Research Methodology
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with a new rubber seal whilst the use of a high temperature PTFE seal was under investigation by the
Horiba Corporation.
Figure 3.10a Rubber seal disintegrate in the SUM NOx converter.
The second most common failure was line blockage, resulting in the analyser failing to calibrate.
During one of the services, deposit build up inside the pipeline to the converter was observed. The
blockage was easily cleaned and removed. It was believed that the white deposit was coming from
surviving urea droplets penetrating the MEXA analyser sampling line filter. Some of the urea droplets
have a tendency to change form to a white deposit when the temperature changes. Urea droplets
should evaporate and release NH3 in the exhaust, but some evidently survived and were sucked into
the MEXA sampling probe and subsequently cooled within the sampling line. This observation was
reported to the Horiba research centre for further investigation.
To resolve this problem, a paper based finger filter had to be replaced for approximately four hours
of sampling. This will prevent any surviving urea droplet from passing through the sampling line and
penetrating the crucial element of the MEXA analyser and also preventing sampling line blockage.
The paper based finger filter is located at the back of the main unit of MEXA analyser as shown in
figure 3.10b
Figure 3.10b Paper based finger filter located at the back of
MEXA 1170Nx Ammonia Analyser
The most severe problem was due to NOx converter failure. In this failure, the carbon converter
used for converting NOx to NO had disintegrated into dust or a powder type material. Initially, a
spherically shape carbon compacted NOx converter was supplied as shown in figure 3.10c. The
New seals / O’ ring
Used seals / O’ ring
finger filter
Chapter 3 Research Methodology
70
converter benefited from a large surface area for the reaction which converts NOx to NO prior to
detection by the CLD analyser unit. It was suspected that some of the unconverted urea droplets
survived the exhaust stream and got into the converter, attacking the carbon.
A new glassy carbon for the NOx converter, shown in fig 3.10d was used to fix this problem. It
features a crystal structure which benefits from low surface area and greater poison resistance. The
glassy carbon converter was gradually consumed each time reaction took place in the NOx oxidation
catalyst. The efficiency of the NOx converter must remain at 90% or higher. Once the efficiency
drops below 90%, it needs replacing. A gas divider is needed for the NOx efficiency check and
certified Horiba engineers are trained to perform the efficiency check.
Figure 3.10c Spherical carbon compact NOx converter
Figure 3.10d New Glassy Carbon NOx Converter
The NH3 oxidation catalyst poisoning was one of the crucial factors which delayed this investigation.
The function of the NH3 oxidation catalyst is to oxidize all NH3 gas to NO to be detected by the CLD
detector. It was first detected during the daily NH3 catalyst efficiency check. The NH3 catalyst
efficiency check was performed by running the analyser calibration at the beginning and the end of
each test. During this check, the NH3 catalyst efficiency was found to be below 80%. At this point the
NH3 measurement is no longer considered acceptable and the oxidation catalyst needs replacing.
It was believed that some of the surviving urea droplets were attacking the NH3 oxidation catalyst.
The NH3 efficiency check was easier to perform as compared to the NOx converter efficiency check.
It only needs the NH3 gas bottle at 95 ppm and the NH3 efficiency was checked daily throughout the
investigation. The daily NH3 efficiency check was included as part of the testing procedure. The final
problem identified with the MEXA was the occurrence of reaction between NO2 and NH3 on the NOx
converter which lead to errors in the measurement of these species.
Chapter 3 Research Methodology
71
The measurement of NO, NO2 and NH3 were performed at the inlet and exit of the SCR catalysts as
described by the test matrix shown in table 3.11b. Due to some interference with the NOx and NH3
measurements in the NOx/NH3 mode and NOx and NO2 in the NO/NO2 mode, some basic
assumption had to be made. The assumption covered the reliability of the measurements taken with
respect to the measurement modes selected. In the NOx/NH3 mode, only the SUM measurements
were correct while the NOx measurements were too low and the NH3 measurements were too high
in the presence of Ammonia.
Figure 3.10e A typical example of erroneous measument of NOx in present of Ammonia.
The typical erroneous measurement of NOx in present of ammonia is shown by the green line in
figure 3.10e. In this example, the NOx measurement was taken upstream of the SCR brick using the
NH3 mode of the MEXA analyser. At the same time, EXSA analyser was also used to measure NOx,
but upstream of the gas injection, shown by the pink line in figure 3.10e.
The spray trigger was denoted by the vertical light blue lines, which indicates the changes of gas
injection setting. As the gas injection started from the second to the fifth minutes, the NOx level
shows decreasing values (green line) as the ammonia level rises (blue line). In the absence of
ammonia, using the EXSA analyser upstream of the gas injection shows the NOx level remains
exNOx 560exNOx 560
mSUM, 545
mSUM >1003
mSUM, 935
mSUM, 826
mSUM, 757
mSUM, 700
mSUM, 600mSUM, 550
mxNOx535
mxNOx 450mxNOx465
mxNOx473
mxNOx476
mxNOx 484mxNOx500
mxNOx 520
NH3 , 15
NH3 600
NH3 484
NH3 362
NH3 286
NH3 220
NH3 100
NH3 30
0
100
200
300
400
500
600
700
800
900
1000
1100
0 2 4 6 8 10 12 14
ppm
time (min)
060808b NH3 up4SCR( 5% gas) 96-0 glass float
exNOx
mSUM
mxNOx
NH3
spray
3248608096 016gas
Chapter 3 Research Methodology
72
unchanged. This interference can be seen for all measurements of NOx in present of ammonia. This
phenomenon was also supported by the finding of Sandip et al., (2007) where, Chemiluminescense
(CLD) based analyser lead to erroneous NOx measurements. They also develop a way to cure this
problem using an ammonia scrubber which prevents the interference of NO2 with ammonia and
poisoning effect of the converter catalysts in CLD NOx analyser. At the time of this investigation, the
use of ammonia scrubbers was still under evaluation by Horiba. Therefore, a special measurement
strategy was developed later discussed in section 3.11 in order to measure NOx and NH3 in the
presence of high concentration of ammonia.
Meanwhile, in the NO/NO2 mode of the MEXA analyser, only NO measurements were correct while
SUM and NO2 measurements were too low. These erroneous measurements were due to reaction
between NH3 and NO2 on the NOx converters in both lines of the analyser. Instead of simply
converting NO2 to NO, the reaction of NO2 with NH3 to produce N2 causes low NOx reading in
NOx/NH3 mode.
It also caused erroneous NOx and NO2 reading in the NO/NO2 mode. The SUM measurements in
NOx/NH3 mode represent the measurement of the total NH3 + NO + NO2. At a later stage, the SUM
readings were used to deduce the NOx and NH3 and later to NO2 by deduction method. The analyser
performance when measuring a mixture of NO, NO2 and NH3 are summarized in table 4.1a below.
Table 3.10a MEXA analyser performance when measuring a mixture of NO, NO2 and NH3
SUM(NO+NO2+NH3) NOx NH3
NOx/NH3 mode Correct Incorrect – too low Incorrect – too high
SUM (NOx) NO NO2
NO/NO2 mode Incorrect – too low Correct Incorrect – too low
Chapter 3 Research Methodology
73
Considering the MEXA analyser limitation in measuring the emission in this investigation, careful
interpretations are needed to analyze the results. Therefore a total of seven set of positive results
have been identified and categorized according to the type of ammonia injected and the number of
SCR brick utilized. The remaining of the measurements was considered as loss and discarded from
the analysis of the results. Two sets of result were obtained from urea spray test comprises of single
SCR brick and four SCR bricks. Four sets were from the 5% ammonia gas test which includes one
through four bricks. Only one set of results were available from the 4% ammonia gas test.
3.11 Final Measurement Strategies.
As stated above due to the interference between NO2 and NH3 on the NOx converter erroneous
measurements resulted when NH3 was present in the gas stream. To circumvent this problem a
measurement strategy was derived which enable measurements of all three gas, NO, NO2 and NH3
to be obtained upstream and downstream of the SCR. The EXSA was used to measure engine out
emissions upstream of the DPF/DOC. The MEXA was used upstream and downstream of the SCR.
The following measurement strategy was used to interpret the MEXA analyser readings. The NO and
NO2 measurements upstream of the SCR were made in the absence of ammonia and it was assumed
that gas phase reactions prior to the SCRs were negligible. Therefore these readings were also valid
in the presence of ammonia. The SUM reading from the analyser in the NOx/NH3 mode in the
presence of ammonia was valid, so the ammonia level could be found by manual subtraction.
In the presence of ammonia slip, downstream of the SCR brick only NO measurement is correct and
reliable. However the readings of the SUM upstream minus the SUM downstream gives a measure
of (NH3 + NOx) consumed by the SCR bricks. Furthermore, an assumption can be made that NOx and
ammonia are mainly consumed on a mol/mol basis during the SCR reactions.
Using this assumption neglects ammonia oxidation and the slow SCR reaction, but is valid as a first
approximation for the temperature range of around 300 OC in this investigation. Therefore, half of
(NH3 + NOx) consumed is either ammonia or NOx consumed. NO consumed is available directly from
Chapter 3 Research Methodology
74
the difference between upstream and downstream measurements. Finally, NO2 consumed is found
from the difference between NOx consumed and NO consumed.
From the direct measurement of NO downstream, the slip of (NH3 + NO2) is found by subtraction of
NO from the measurements of SUM (NH3 + NO2 + NO). In the case of 4% and 5% ammonia gas in N2
injection, the input level can be determined from a calibrated flow meter and the known exhaust
mass flow rate. This information can be used to check upstream measurements. For urea spray
injection, the potential ammonia injected can be determined from the spray mass flow rate.
By comparison of this with the measured ammonia upstream of the SCR will indicate the mass of
spray that has released its ammonia between the spray point and the emissions measurement
location. The magnitude of the potential SUM upstream (potential NH3 + NO + NO2) minus the
measured SUM downstream should indicate the total consumption of all species (NH3 + NO + NO2) in
the SCR bricks. This condition is valid with the assumption that no droplets pass through the SCRs.
The comparison between urea injection and NH3 gas injection in the 1 SCR case would generally give
some idea of what happened to the droplets within the SCR brick. Finally the tests were carried out
for 1, 2, 3 and 4 SCRs with ammonia gas injection but only 1 SCR and 4 SCR test cases were
implemented using urea spray. All of the measurements were made as a function of ammonia level
input. The measurement capability of the MEXA analyzer in the investigation is summarized in table
3.11a.
Chapter 3 Research Methodology
75
Table 3.11a Measurement strategy when using Horiba MEXA 1170Nx Ammonia analyzer
NH3 Gas case
Sampling
Upstream SCR
NH3 Gas Case
Sampling
Downstream
SCR
Spray Case
Sampling
Upstream SCR
Spray Case
Sampling
Downstream
SCR
SUM =
(NH3+NO+NO2) OK OK OK OK
NH3 Subtraction
(SUM-NOx)
OK
If low NH3 slip
Subtraction
(Potential SUM-NOx)
OK
If low NH3 slip
NOx Measure with
gas off
OK
If low NH3 slip
Measure upstream of spray
with spray off
OK
If low NH3 slip
NO Measure with
gas off
OK
If low NH3 slip
Measure upstream of spray
with spray off
OK
If low NH3 slip
NO2 Measure with
gas off
OK
If low NH3 slip
Measure upstream of spray
with spray off
OK
If low NH3 slip
Note: Downstream measurements with high NH3 levels ideally need an ammonia scrubber which was not available for MEXA at the time of
this study.
These restrictions, have resulted in different measurements mode (either NH3/NOx or NO2/NO) to
be conducted in separate environments. After the final measurement strategies have been fully
develop the sampling locations of EXSA and MEXA analysers along the SCR exhaust system were
finalized. The experiment was carried out according to the test matrix shown in table 3.11b.
Location
Measure
Chapter 3 Research Methodology
76
Table 3.11b Experimental Test Matrix with urea spray and NH3 gas
Up DPF
1st module Spray /Gas 2nd module 3rd module
SCR Bricks
length 4th module
Test A EXSA Capped Spray capped Lambda1 MEXA1
Single (1x) 91 mm
Lambda2 MEXA2
Test B EXSA capped Spray capped Lambda1 MEXA1
Quad (4x) 364 mm
Lambda2 MEXA2
Test 1 EXSA NH3 gas Capped capped Lambda1 MEXA1
Single (1x) 91 mm
Lambda2 MEXA2
Test 2 EXSA NH3 gas Capped capped Lambda1 MEXA1
Double (2x) 182 mm
Lambda2 MEXA2
Test 3 EXSA NH3 gas Capped capped Lambda1 MEXA1
Triple (3x) 273 mm
Lambda2 MEXA2
Test 4 EXSA NH3 gas Capped capped Lambda1 MEXA1
Quad (4x) 364 mm
Lambda2 MEXA2
3.12 Summary of Final Experimental Procedures.
Despite of all the obstacles experienced in the investigation, remedial action was taken and a series
of test procedures was adopted in order to ensure a valid and consistent result throughout. The final
experimental procedures implemented in the investigation are summarized as follows:
• Allow engine warm up for engine condition of 1500 rpm and load of 6 bars BMEP until the
exhaust temperature in final module reached 300 OC.
• Record exhaust mass flow rate for every gas or urea injection settings used.
• Measure O2 upstream and downstream of SCR bricks.
• Allow EXSA and MEXA calibrations to be completed before and after each test. MEXA
efficiency check needs to be maintained for internal oxidation catalyst to be above 90% at all
time and the NOx converter efficiency was assumed to be 100%
• Measure NOx out from engine using EXSA NOx Analyser downstream of DOC.
• Measure NO, NO2, NOx upstream of the SCR using MEXA Analyser
• For urea injection, check spray outside the mixing chamber prior to fitting within the SCR
exhaust system. Spray pulse rate setting range from 24 to 36 ms.
Chapter 3 Research Methodology
77
• Inject Gas (4% or 5%) in the first module or Urea in the expansion box for uniform mixing
upstream of SCR.
• Adjust gas flow rate from 0 to 120 mm for 4% and 0 to 96 mm for 5% gas. For urea injection,
pulse rate setting used is from 24 to 36 ms.
• Measurements of all species must be allowed to reach a steady value before changing to a
different urea spray or ammonia gas injection settings.
• Measure NOx,NH3 upstream of SCR using MEXA Analyser
• Measure NO, NOx and NH3 downstream of SCR using MEXA Analyser.
• Vary the SCR bricks length from 91 mm in length, four were available, then repeat the
measurement upstream and downstream of SCR with 2x,3x and 4x SCR.
3.13 Example of measurements strategy applied
All the measurements obtained in this study are given in full in Appendix 4. Each graph in appendix 4
has a code name derived from the details of the experiment and the date on which it was
performed. The code name is printed at the top of each graph. Appendix 4.0 has a list of contents at
the beginning which should enable each experiment to be found. For example, “9jul08b NH3 dw
1SCRL” is a measurement trace obtained on 9/7/2008 of NH3 downstream of the 1 SCR, and L refers
to LHS of the original plot
An example of the test with 5% ammonia gas injected upstream of 1 SCR brick is selected and the
engine log is shown in figure 3.13. In this engine log, the MEXA analyser was used upstream of the
SCR in NH3 mode measuring SUM, NOx and NH3 as described earlier in section 3.4.4. The EXSA
analyser was measuring NOx upstream of the 5% gas injection point to provide the engine NOx out.
The code name for this test “12aug08 bNH3 up1SCR 5% L2” refers to the engine log data 120808b
nh3 up1scr, which refers to the actual date the test was performed.
The code “b” refers to the second data log after the engine warm up and analysers calibration had
been completed, which had a code “a”. The name NH3 up1SCR 5% L2 refers to the NH3 mode of
MEXA analyser with sampling location upstream of the SCR brick with the 5% ammonia gas injected.
This whole test was performed from high gas injection rate setting to low, then low to high, and
again high to low. The code L2 refers to the final high to low gas injection setting from the overall
engine log from time 17th to 25th minute.
Chapter 3 Research Methodology
78
Figure 3.13 Example of engine log from 5% ammonia gas with 1 SCR brick.
From the figure 3.13 above, the engine NOx out from EXSA showed a consistent 575 to 580 ppm
(labelled exNOx) from the 17th to 25th minute shown by the trace in pink. The changes of gas setting
were indicated by the vertical light blue line. Starting from gas injection setting at 96 mm (see
appendix 3.7.1c for details), the SUM reading was showing over (noted by >1004), the NH3 reading
was 636 ppm (in blue) and mNOx (from MEXA) was 452 ppm in green. As previously described, the
NOx reading from MEXA was taken with the gas off. As the gas injection setting was reduced in steps
from 96 to 80, 60, 48, 32, 16 and finally 0, the SUM and NH3 level also reduces accordingly.
At each gas injection setting, the SUM and NH3 readings were allowed to settle down to steady state
for about a minute before the next gas injection setting was selected. The SUM trace is shown in
brown. This methodology of systematic variation of settings and allowance of sufficient time for the
analyzer reading to reach steady state was applied to all measurements in this study. The results are
all presented and discussed in the next chapter.
exNOx 575
exNOx , 575exNOx 580
mSUM >1004mSUM , 964
mSUM , 845mSUM , 780
mSUM 725
mSUM , 620mSUM 575 mSUM 565
mNOx 452 mNOx 463 mNOx 473mNOx 485 mNOx 491 mNOx , 511
mNOx 537
NH3 636
NH3 523
NH3 385
NH3 309NH3 245
NH3 , 111
NH3 , 430
100
200
300
400
500
600
700
800
900
1000
1100
17 18 19 20 21 22 23 24 25
ppm
time(min)
12aug08b bNH3 up1SCR 5% L2
exNOx
mSUM
mNOx
NH3
spray
320.2psi
480.4psi
600.5psi
800.7psi
961psi
160.1psi
gas off0
Chapter 4 Experimental Results and Discussions
79
CHAPTER 4: EXPERIMENTAL RESULTS AND DISCUSSIONS
4.0 Experimental results: Introduction
In this chapter, the experimental results are obtained based on the experimental methodology
described in chapter 3. These tests include the use of urea spray, 5% and 4% NH3 gas. The urea spray
experiments were performed with a single and quadruple SCR bricks. For the 5% NH3 gas,
experiments were conducted by varying the SCR bricks from single up to quadruple bricks. The
experiment with 4% NH3 gas was carried out with only a single SCR brick. The data were obtained
from these experiments using the MEXA analyser by sampling upstream and downstream of the SCR
bricks. Information about NO2 and NH3 levels could be obtained by analysis described in the
following sections. Most of the tests were carried out under steady state conditions, but this chapter
also discusses some aspects of transient behaviour. Finally the features of the SCR process revealed
by the measurements are discussed.
4.1.0 Urea spray studies: General overview
The main difference between the gas and the spray studies is the upstream NH3 level. In the gas
studies, the upstream NH3 was readily available whilst for the spray studies; the upstream NH3 was
potentially available from the decomposition of the urea. Each urea molecule within the droplets
must first decompose into an ammonia molecule and an HCNO (iso-cyanic acid molecule). This
occurs at temperature of approximately 130 to 137 OC.
The iso-cyanic acid molecule must then react with water to produce a further ammonia molecule.
This hydrolysis reaction is more likely to occur on a catalyst surface rather than in the gas phase, and
will be more rapid at higher temperatures. Therefore the upstream deduced measurement of
ammonia in these studies is only part of the ammonia potentially available for the SCR reactions on
the catalyst bricks. From the known spray pulse length setting, the spray calibration and the known
exhaust mass flow rate, the “potential ammonia” introduced into the exhaust in ppm can be
calculated, see Appendix 3.6.2
Chapter 4 Experimental Results and Discussions
80
4.1.1 Urea spray studies: Upstream Measurements (1 and 4 SCR bricks)
At the location upstream of the SCR bricks with the MEXA in NH3/NOx mode the following equation
applies,
SUM upstream = [NH3 +NO +NO2]
Thus, for potential values,
Pot SUM upstream = [potential NH3+NO + NO2]
Pot SUM is calculated from the potential ammonia and from NO and NO2 measurement taken when
the spray was off. The NOx upstream is measured without the spray injection and is assumed to
remain the same when the spray is injected due to the assumption that the gas phase reactions are
negligible. The NO upstream can be measured, even with the presence of ammonia using the MEXA
analyser in NO/NO2 mode. Similarly, the assumption is made that no gas phase reactions occur.
4.1.2 Urea spray studies: Downstream Measurements (1 and 4 SCR bricks)
The measurement with the MEXA in NH3/NOx mode downstream of the SCR bricks will give the SUM
downstream, which effectively represent the NH3, NO and NO2 coming out from the SCR bricks.
Thus,
SUM downstream = [NH3 + NO + NO2]
The NOx downstream can generally be measured only with the spray off, unless the ammonia slip is
very minimal. In the spray experiments, in all cases, the ammonia slip was significant. This is because
the spray was designed for heavy duty vehicles and would not operate effectively at lower urea flow
setting. Therefore, all of the experiments with the spray were carried out under excess spray
conditions. The NO downstream could be measured even in the presence of ammonia slip by using
MEXA in the NO/NO2 mode. The NH3 downstream reading is erroneous with the MEXA when the
ammonia slip level is significantly above zero, which occurred in most of the experiments with spray.
However,
[ SUM - NO ] = [ NH3 + NO2 ].
Thus, the two useful pieces of downstream information are the NO levels and [NH3 + NO2] levels and
would be useful for CFD validation.
Chapter 4 Experimental Results and Discussions
81
4.1.3 Urea spray studies: Deduced value.
To deduce NH3, and NO2, it was necessary to use the difference between the potential SUM
upstream and the SUM downstream in this case. Therefore, using the following equation
Pot SUM upstream – SUM downstream = [NH3 + NO + NO2] consumption in the catalyst.
The implication of this is the assumption that SUM downstream is the true measurement of the
ammonia gas plus the NOx with no droplets or HNCO passing through the catalyst. This assumption
may not be true for the 1 SCR, where ammonia in droplet form (or possibly as HNCO) at the catalyst
exit is unaccounted for. But, it should however be true for the 4 SCR bricks case. It is again
reasonable to assume that these species can only be consumed if they react with one another, and
that they react on a mol NH3 per mol NOx basis. It also neglects non mol to mol reactions and
ammonia oxidation. There may be also additional reactions with urea by products that are
neglected. Therefore,
½ [NH3 + NO + NO2] consumed = NH3 consumed = NOx consumed
NO consumed can be found directly from
[NO upstream – NO downstream]
Hence,
NO2 consumed = [NOx consumed – NO consumed]
4.1.4 Urea sprays studies: Ammonia levels upstream of SCR bricks.
In getting the ammonia levels, the calibrated spray pulse length setting and the knowledge of the
exhaust mass flow rate can be used to calculate the potential ammonia level in ppm at location
upstream of the SCR. This can be compared with the deduced value obtained from [SUM-NOx]. The
difference between the levels would give an indication of how many of the droplets have released
their ammonia between the spray injection point and the gas analysis measurement point upstream
of the SCR. The 1 SCR and 4 SCR cases give remarkably different amounts of ammonia released from
the droplets upstream of the SCR. It is not immediately apparent why this should happen, as the
temperatures in the two experiments were very much similar and the main difference was the SCR
resistance to the flow. This is further discussed in section 4.5.1.
Chapter 4 Experimental Results and Discussions
82
4.1.5 Measurement with Urea Spray and 1 SCR brick.
Table 4.1.5 summarizes the test results associated with urea spray and 1 SCR brick. Potential
ammonia release from the urea spray was also calculated. The NH3 reading upstream from MEXA
was recorded and clearly does not represent the correct NH3 values. The SUM readings previously
introduced in section 4.1.1 have been recorded from several set SUM readings and the average
values were used in this table compiled from data shown in appendix 4.1.5b. Upstream of SCR, direct
measurement of SUM, NO, NOx and NH3 were tabulated in the table. For downstream
measurements, only SUM, NO and NH3 were obtained directly from MEXA.
Table 4.1.5 Summary of Result: Urea Spray with 1 SCR. (all measurements in ppm)
Results for urea spray (1 SCR)Temp upstream 573 KTemp downstream 574 KO2 upstream 9.70%O2 downstream 7.90%
1 SCR Spray pulse length (ms) --> Description 0 24 26 28 30 32 34 36 Refn Guide Apdx
Potential up 1SCR Potential NH3 0 552 614 696 818 888 960 1042 calc A 3.6.2
Potential up 1SCR Potential SUM 505 1057 1119 1201 1323 1393 1465 1547Pot(nh3
+nox)B
MEXA up 1SCR SUM 550 645 680 700 723 734 754 761 avg sum C 4.1.5bMEXA, Spray off up 1SCR NO 196 196 196 196 196 196 196 196 070708a D 4.1.5MEXA, Spray off up 1SCR NOx 505 505 505 505 505 505 505 505 090708c E 4.1.5
Calculated up 1SCR NO2 309 309 309 309 309 309 309 309 nox-no FMEXA Reading up 1SCR NH3 21 210 250 290 310 320 345 385 090708c G 4.1.5
Deduced ammonia up 1SCR SUM-NOx 45 140 175 195 218 229 249 256 sum-nox C-E=H
MEXA dw 1SCR*SUM(excludes
drops) 539 495 564 607 661 732 797 863 avg sum I 4.1.5b
MEXA dw 1SCR NO 200 137 139 139 140 140 140 140 070708b J 4.1.5MEXA Reading dw 1SCR NH3 21 222 312 395 450 513 614 680 090708b K 4.1.5
NH3 + NO2 dw 1SCR SUM-NO 339 358 425 468 521 592 657 723 calc I-J=L
NH3 + NOx consumedacross 1
SCRPotential SUM-
SUM (*) -34 562 555 594 662 661 668 684 calc B-I=M(*) Value too large because downstream sum was too small as it excluded drops
Note: Plotted against potential ammonia supplied 1 SCR sprayPot NH3 up 0 552 614 696 818 888 960 1042 A
up - down, 1SCR SUM-SUM 1SCR -34 562 555 594 662 661 668 684 M
1SCR spray NOx or NH3 consumed -17 281 278 297 331 331 334 342 M/2=N
1SCR spray NO consumed -4 59 57 57 56 56 56 56 D-J=O
1SCR spray NO2 consumed -13 222 221 240 275 275 278 286 N-O =P
concentration table pot NH3 up 0 552 614 696 818 888 960 1042 A
Deduced ammoniaupstream 1SCR SUM-NOx 45 140 175 195 218 229 249 256 H
NH3 17 271 337 399 487 558 626 700 A-N
NOx 522 224 228 208 174 175 171 163 E-N
NO 200 137 139 139 140 140 140 140 D-O
NO2 322 87 88.5 69 34 34.5 31 23 F-P
Downstream
Chapter 4 Experimental Results and Discussions
83
Three columns on the right side of table 4.1.5 give reference to the actual data log in appendix 4,
provide a guide on how to read the table and refer to related appendix for the data in respective
rows.
4.1.6 Measurement with Urea Spray and 4 SCR bricks.
The test results with urea spray and 4 SCR bricks are summarized in the table 4.1.6. The same
methodology used for Urea Spray with 1 SCR was utilised in this test. The main differences from the
1 SCR case is the NOx reading downstream of the SCR. Clearly in this test, excess ammonia from urea
spray have reduced all of NOx but posses another problem in the system. The undesired NH3
slippages have been detected and further analysis in the section 4.1.6 will discuss this in depth.
Table 4.1.6 Summary of Result: Urea Spray with 4 SCR. (all measurements in ppm)
Results for urea spray (4 SCRs)Temp upstream 592 KTemp downstream 582 KO2 upstream 9.30%O2 downstream 7.90%
4 SCRs Spray pulse length (ms) --> 0 24 26 28 30 32 34 36 Refn Guide Apdx
Potential up 4SCR Pot NH3 0 552 614 696 818 888 960 1042 calc A 3.6.2Potential up 4SCR Pot SUM 510 1062 1124 1206 1328 1398 1470 1552 nh3+nox B
MEXA up 4SCR SUM 544 797 813 837 858 878 904 908 avg sum C 4.1.6BMEXA, Spray off up 4SCR NO 200 200 200 200 200 200 200 200 240708b D 4.1.6MEXA, Spray off up 4SCR NOx 510 510 510 510 510 510 510 510 240708b E 4.1.6
Calculated up 4SCR NO2 310 310 310 310 310 310 310 310 calc FMEXA Reading up 4SCR NH3 38 318 346 381 405 434 466 240708b G 4.1.6
Deduced ammonia up 4SCR SUM-NOx 34 287 303 327 348 368 394 398 240708b C-E=H 4.1.6
MEXA dw 4SCR SUM 539 78 128 181 242 304 367 424 avg sum I 4.1.6MEXA dw 4SCR NO 205 30 5 1 1 1 2 20708c J 4.1.6
Measured dw 4SCR NH3 0 79 136 167 225 310 375 230708b K 4.1.6NH3 + NO2 dw 4SCR SUM-NO 334 48 123 180 241 303 365 424 calc I-J=L
Total consumedacross 4 SCrs Pot SUM-
SUM -29 984 996 1025 1086 1094 1103 1128 calc B-I=M
Note: Plotted against potential ammonia supplied 4 SCR sprayPot NH3 up 0 552 614 696 818 888 960 1042 A
up - down, 4SCR Pot SUM-SUM 4 SCR -29 984 996 1025 1086 1094 1103 1128 M
4SCR spray NOx or NH3consumed -15 492 498 512.5 543 547 551.5 564 M/2=N
4SCR spray NO consumed -5 170 195 199 199 199 198 200 D-J=O
4SCR spray NO2 consumed -9.5 322 303 313.5 344 348 353.5 364 N-O =P
concentration table pot NH3 up 0 552 614 696 818 888 960 1042 ADeduced ammonia ups 4SCR SUM-NOx 34 287 303 327 348 368 394 398 H
NH3 14.5 60 116 183.5 275 341 408.5 478 A-N
NOx 525 18 12 -2.5 -33 -37 -41.5 -54 E-N
NO 205 30 5 1 1 1 2 0 D-O
NO2 320 -12 7 -3.5 -34 -38 -43.5 -54 F-P
Downstream
Chapter 4 Experimental Results and Discussions
84
At the bottom of table 4.1.6 some of the NOx and NO2 reading were showing negative values due to
experimental error in this study using the methodology described earlier in the range of around +/-
55 ppm. The NO2 measurements were not measured directly but derived using the methodology
described in section 4.1. It is believed that the negative values reflect the magnitude of the errors
resulting from these assumptions, but do not affect the general conclusions discussed later.
4.2 Ammonia gas studies: General Overview
The test with 5% and 4% ammonia gas provide a comparison of SCR reaction in the form of gas as
compared to aqueous ammonia solution. The ammonia input level can be determined from known
exhaust mass flow rate and a calibrated flow meter. The advantages using ammonia gas is obviously
to accelerate the SCR reaction to reduce NOx and eliminate the complication with the use of urea
spray. The analyser response to the measurements also improved and also reduced analyser break
down due to urea droplets penetrating the sampling lines and internal components of the analyser.
Five cases are presented in this investigation involving four 5% tests and one 4% test.
4.2.1 Ammonia gas studies: upstream measurements. (1 and 4 SCR bricks)
The measurements taken for the 4% and 5% ammonia gas were the SUM upstream and downstream
of the SCR and the NO upstream and downstream of the SCR. The SUM in NOx/NH3 mode of the
MEXA follows the equation below:
SUM upstream = [NH3 +NO +NO2] upstream
The NOx measurements upstream were obtained in the absence of ammonia gas injection and were
assumed unchanged when ammonia gas was injected. This assumes that the gas phase reactions
were negligible. In the MEXA NO/NO2 mode, the NO measurements upstream, even in the presence
of ammonia, should be the same as without the ammonia gas injection as the converter is bypassed.
Similarly, the assumption made was no gas phase reactions occurred. Therefore, the NO2 upstream
can be deduced from NOx-NO and had the same value regardless of amount of ammonia injected.
The NH3 measurements recorded upstream were erroneous but the correct ammonia level could be
obtained by calculation of SUM-true NOx.
Chapter 4 Experimental Results and Discussions
85
4.2.2 Ammonia gas studies: downstream measurements. (1 and 4 SCR bricks)
The SUM measurements downstream of the SCR bricks were also valid using the MEXA in NOx/NH3
mode similar to the upstream measurements. The SUM measurement downstream is given as the
equation below:
SUM downstream = [NH3 +NO +NO2] downstream
NOx measurements downstream are only valid with no ammonia gas injection present or with very
minimal ammonia slip. If the latter was true, for cases with more than 1 SCR bricks, then the
measured NOx level downstream was additional information available in these cases. The NO
measurements downstream were always valid using the MEXA in the NO/NO2 mode even with the
presence of ammonia slip. The NO2 values downstream with gas off can be deducted from NOx-NO
and it is also available for cases where gas injection dosing was very low and where ammonia slip
was minimal. The NH3 downstream measurements were erroneous with the MEXA at any ammonia
levels significantly above zero. However, the following equation is true:
[SUM-NO] = [NH3+NO2].
Therefore the two useful pieces of downstream data are the NO levels and [NH3+NO2] levels and
these could be used for CFD model validation. The NO2 levels downstream are also available for the
low dose cases where approximately zero ammonia slips occurred.
4.2.3 Ammonia gas studies: Deduced values.
The gaseous consumption in the catalyst could be easily obtained via deductions by the following
equation:
SUM upstream - SUM downstream = [NH3 + NO + NO2] consumption in the catalyst.
Chapter 4 Experimental Results and Discussions
86
Reasonably, it is safe to assume that these species can only be consumed in the SCR if NOx reacts
with NH3. Furthermore, it is reasonable to assume that a mol of NH3 reacts with a mol of NOx thus
neglecting non-mol to mol reactions and ammonia oxidation.
Consequently,
½ [NH3 +NO +NO2] consumed ≈ NH3 consumed ≈ NOx consumed
Therefore, the NO consumed can be found directly from,
[NO upstream-NO downstream]
and similarly the NO2 consumed from,
NO2 consumed = [NOx consumed-NO consumed]
4.2.4 Ammonia gas studies: Ammonia levels
From the calibrated gas flow meter setting used, together with the knowledge of the exhaust mass
flow rate, the injected ammonia level in ppm upstream of the SCR can be calculated. This is shown in
the appendices 3.7.1a to d. Then, this information can be compared with the deduced value
obtained from [SUM-NOx]
Chapter 4 Experimental Results and Discussions
87
4.2.5 Measurement with 5% Ammonia Gas and 1 SCR brick.
The test results for 5% ammonia gas with 1 SCR brick are shown in table 4.2.5. In this table only SUM
and NO readings were directly obtained from the MEXA measurements upstream and downstream
of the SCR brick. The NOx value upstream was assumed constant due to no ammonia gas present
during the measurement.
Table 4.2.5 Summary of Result: 5% Ammonia Gas with 1 SCR. (all measurements in ppm)
4.2.6 Measurement with 5% Ammonia Gas and 2 SCR bricks.
The test results with 5% ammonia gas and 2 SCR are presented in the table 4.2.6. In this test, similar
method as the 1 SCR was utilised but this time with 2 SCR bricks. The MEXA analyser was measuring
NOx and NH3 and SUM upstream and downstream of the 2 SCR bricks. At this stage, the NO data was
not recorded downstream, therefore restricting the analysis to only NOx and NH3 consumed. The
information on NO and NO2 consumed could have become available with the NO data downstream
Results for 5% NH3 in N2 gas and 1SCR Temp upstream 596 KTemp downstream 582 KO2 upstream 8.8%O2 downstream 7.6%
1 SCRFlowmeter setting (glass float) --> 0 16 32 48 60 80 96 Refn Guide Apdx
MEXA up SUM 575 620 725 780 845 964 1088 120808b A 4.2.5MEXA, Gas off up NO 230 230 230 230 230 230 230 210808c B 4.2.5MEXA, Gas off up NOx 539 539 539 539 539 539 539 120808b C 4.2.5
Calculated up NO2 309 309 309 309 309 309 309 calc C-B=DMEXA Reading up NH3 52 111 245 309 385 523 636 120808b E 4.2.5
Deduced ammonia up SUM-NOx 36 81 186 241 306 425 549 calc A-C =F
MEXA down SUM 578 513 470 476 495 579 669 120808c G 4.2.5MEXA down NO 214.13 188.86 162.26 155.61 150.29 147.63 155.61 avg NO H 4.2.5b
MEXA Reading down NH3 38 46 82 114 168 279 389 120808c I 4.2.5NH3 + NO2 down SUM-NO 363.87 324.14 307.74 320.39 344.71 431.37 513.39 calc G-H=JNH3 + NOx consumed up - down SUM-SUM -3 107 255 304 350 385 419 calc A-G=K
5% gas 1 SCR0 16 32 48 60 80 96
575 620 725 780 845 964 1088 ANH3 36 81 186 241 306 425 549 F
up - down, 1SCR SUM-SUM 1SCR -3 107 255 304 350 385 419 K
up - down, 1SCR 5% NOx or NH3 consumed -1.5 53.5 127.5 152 175 192.5 209.5 K/2=L
up - down, 1SCR 5% NO consumed 15.87 41.14 67.74 74.39 79.71 82.37 74.39 B-H=M
up - down, 1SCR 5% NO2 consumed -17.37 12.36 59.76 77.61 95.29 110.13 135.11 L-M=N
concentration table NH3 up 0 16 32 48 60 80 96Deduced ammonia up 1SCR SUM-NOx 36 81 186 241 306 425 549 F
NH3 37.5 27.5 58.5 89.0 131.0 232.5 339.5 F-L
NOx 540.5 485.5 411.5 387.0 364.0 346.5 329.5 C-L
NO 214.1 188.9 162.3 155.6 150.3 147.6 155.6 B-M
NO2 326.4 296.6 249.2 231.4 213.7 198.9 173.9 D-N
Downstream
Chapter 4 Experimental Results and Discussions
88
of the 2 SCR. This is mainly due to time constraint involving the relocation of the engine test bed.
Therefore the analysis associated with NO and NO2 for the 2 SCR bricks cannot be performed. The
analysis done on this test case only focussed on the NOx and NH3 consumed by the 2 SCR bricks.
Table 4.2.6 Summary of Result: 5% Ammonia Gas with 2 SCR. (all measurements in ppm)
4.2.7 Measurement with 5% Ammonia Gas and 3 SCR bricks.
The test results with 5% ammonia gas and 3 SCR bricks are summarized in table 4.2.7. For the 3 SCR
bricks, similar test was performed and data was recorded accordingly. The NO and NO2 data
downstream was also unavailable therefore restrict further analysis.
Results for 5% NH3 in N2 gas and 2 SCRs Temp upstream 592 KTemp downstream 581 KO2 upstream 9.1%O2 downstream 7.7%
2 SCRsFlowmeter setting (glass float) --> 0 16 32 48 60 80 96 Refn Guide Apdx
MEXA up SUM 567 608 710 770 824 935 1052 110808b A 4.2.6MEXA up NO 231 231 231 231 231 231 231 210808c B 4.2.6
MEXA, Gas off up NOx 542 542 542 542 542 542 542 110808b C 4.2.6Calculated up NO2 311 311 311 311 311 311 311 110808b C-B=D 4.2.6
MEXA Reading up NH3 31 98 218 282 352 482 589 110808b E 4.2.6Deduced ammonia up SUM-NOx 25 66 168 228 282 393 510 calc A-C =F
MEXA down SUM 556 476 361 297 226 101 14 110808c G 4.2.6MEXA down NO 231 210808c H 4.2.6
MEXA,OK-low NH3 down NOx 548 470 354 297 224 100 9 110808c I 4.2.6Calculated down NO2 317 calc I-H=J
MEXA Reading down NH3 6 6 7 4 3 3 4 110808c 4.2.6NH3 + NO2 down SUM-NO 325 calc G-H=K
Deduced NH3 down SUM-NOx 8 6 7 0 2 1 5 calc G-I=L
5% gas2 SCR0 16 32 48 60 80 96
567 608 710 770 824 935 1052 ANH3 25 66 168 228 282 393 510 F
up - down, 2SCR SUM-SUM 2SCR 11 132 349 473 598 834 1038 A-G=M
up - down, 2SCR NOx or NH3 consumed 5.5 66 175 237 299 417 519 M/2=NNOx downstream 537 476 368 306 243 125 23.0 C-N
Chapter 4 Experimental Results and Discussions
89
Table 4.2.7 Summary of Result: 5% Ammonia Gas with 3 SCR. (all measurements in ppm)
4.2.8 Measurement with 5% Ammonia Gas and 4 SCR bricks.
The test results with 5% ammonia gas and 4 SCR bricks are summarized in table 4.2.8.The final set of
test with 5% ammonia gas was with the 4 SCR bricks. Similar to the 5% and 1 SCR tests, a complete
set of tests were available including NOx, NH3 and NO for further analysis. So, the NOx, NH3, NO and
NO2 consumed within the 4 SCR bricks was obtained using the method previously described.
Results for 5% NH3 in N2 gas and 3 SCRs Temp upstream 595KTemp downstream 584KO2 upstream 9.0%O2 downstream 7.7%
3 SCRsFlowmeter setting (glass float) --> 0 16 32 48 60 80 96 Refn Guide Apdx
MEXA up SUM 583 628 729 777 835 956 1080 070808b A 4.2.7MEXA up NO 231 210808c B 4.2.6
MEXA, Gas off up NOx 550 550 550 550 550 550 550 070808b C 4.2.7Calculated up NO2 319 calc C-B=D
MEXA Reading up NH3 32 104 236 295 371 500 618 070808b E 4.2.7Deduced ammonia up SUM-NOx 33 78 179 227 285 406 530 calc A-C =F
MEXA down SUM 566 490 373 309 244 95 11 070808c G 4.2.7MEXA down NO 231 210808c H 4.2.6
MEXA,OK-low NH3 down NOx 553 480 360 305 238 91 7 070808c I 4.2.7Calculated down NO2 322 calc I-H=J
MEXA Reading down NH3 10 10 9 7 5 2 1 070808c 4.2.7NH3 + NO2 down SUM-NO 335 calc G-H=K
Deduced NH3 down SUM - NOx 13 10 13 4 6 4 4 calc G-I=L
5% gas 3 SCR0 16 32 48 60 80 96
583 628 729 777 835 956 1080 ANH3 33 78 179 227 285 406 530 F
up - down, 3SCR SUM-SUM 3SCR 17 138 356 468 591 861 1069 A-G=M
up - down, 3SCR NOx or NH3 consumed 8.5 69 178 234 296 431 535 M/2=NNOx Downstream 542 481 372 316 255 120 15.5 C-N
Chapter 4 Experimental Results and Discussions
90
Table 4.2.8 Summary of Result: 5% Ammonia Gas with 4 SCR. (all measurements in ppm)
4.2.9 Measurement with 4% Ammonia Gas and 1 SCR bricks.
The test results with 4% ammonia gas and 1 SCR brick are summarized in table 4.2.9. The 4% and 1
SCR test was conducted in a similar way as the 5% and 1 SCR. The main difference is the ammonia
gas injection flow meter setting used. For the 4% ammonia gas test, the flow meter setting used was
higher. Later it was discovered that the 4% ammonia gas was unsuitable for the test due to short
testing capability. On average the 4% ammonia gas bottle can be utilized for approximately 4 hours
of testing. The potential ammonia injected with the 4% and 5% is summarized in appendix 3.10.4.
Results for 5% NH3 in N2 gas and 4 SCRs Temp upstream 594 KTemp downstream 584 KO2 upstream 9.1%O2 downstream 7.9%
4 SCRsFlowmeter setting (glass float) --> 0 16 32 48 60 80 96 Refn Guide Apdx
MEXA up SUM 550 600 700 757 826 935 1050 060808b A 4.2.8MEXA up NO 213 213 212 212 210 210 207 060808c B 4.2.8
MEXA, Gas off up NOx 527 527 527 527 527 527 527 060808b C 4.2.8Calculated up NO2 314 314 315 315 317 317 320 calc C-B=D
MEXA Reading up NH3 30 100 220 286 362 484 600 060808b E 4.2.8Deduced ammonia up SUM-NOx 23 73 173 230 299 408 523 calc A-C =F
MEXA down SUM 550 472 353 283 217 87 8 060808e G 4.2.8MEXA down NO 214 170 122 100 75 25 2 060808d H 4.2.8
MEXA,OK-low NH3 down NOx 536 460 344 275 210 83 4 060808e I 4.2.8Calculated down NO2 322 290 222 175 135 58 2 calc I-H=J
MEXA Reading down NH3 14 11 10 8 6 4 3 060808e 4.2.8NH3 + NO2 down SUM-NO 336 302 231 183 142 62 6 calc G-H=K
Deduced NH3 down SUM-NOx 14 12 9 8 7 4 4 calc G-I=LNH3 + NOx consumed up - down SUM-SUM 0 128 347 474 609 848 1042 calc A-G=M
5% gas 4 SCR0 16 32 48 60 80 96
550 600 700 757 826 935 1050 ASUM - NOx = NH3 23 73 173 230 299 408 523 F
up - down, 4SCR SUM-SUM 4SCR 0 128 347 474 609 848 1042 A-G=N
up - down, 4SCR 5% NOx or NH3 consumed 0 64 174 237 305 424 521 N/2=O
up - down, 4SCR 5% NO consumed -1 43 90 112 135 185 205 B-H=P
up - down, 4SCR 5% NO2 consumed 1 21 84 125 170 239 316 O-P=Q
concentration table NH3 up 0 16 32 48 60 80 96Deduced ammonia up 4SCR SUM-NOx 23 73 173 230 299 408 523 F
NH3 23 9 -1 -7 -6 -16 2 F-O
NOx 527 463 354 290 223 103 6 C-O
NO 214 170 122 100 75 25 2 B-P
NO2 313 293 232 190 148 78 4 D-Q
Downstream
Chapter 4 Experimental Results and Discussions
91
Table 4.2.9 Summary of Result: 4% Ammonia Gas with 1 SCR. (all measurements in ppm)
4.3 Analysis of measurement results against ammonia input/potential ammonia input.
In order to summarized the results in this investigation, the detail measurements of NOx, NO, NO2
and NH3 entering and exiting the SCR is needed. From this information the species consumed within
the SCR brick can be analysed. As previously shown in the previous sections (4.1.5 to 4.1.6 and 4.2.5
to 4.2.9) the NO, NO2, NOx and NH3 data are only available for the 1 and 4 SCR bricks. The 2 and 3
brick cases lack NO information downstream therefore cannot be used to analyse the NO and NO2
species consumed within the SCR. In this analysis, the results from 1 SCR and 4 SCR of the 4%, 5% gas
and urea spray are plotted with respect to the ammonia input or potential ammonia input for urea
spray. Figure 4.3 shows the summary of measurement with 1 and 4 SCR bricks for urea spray, 4%
and 5 % gas.
Results for 4% NH3 in N2 gasTemp upstream 592 KTemp downstream 573 KO2 upstream 9.50%O2 downstream 8.30%
1 SCRFlowmeter setting (steel float) --> 0 40 50 60 75 100 120 Refn Guide Apdx
MEXA up SUM 592 824 914 1118 1360 1580 100608b A 4.2.9MEXA, Gas off up NO 209 209 209 209 209 209 209 100608c B 4.2.9MEXA, Gas off up NOx 565 565 565 565 565 565 565 100608b C 4.2.9
Calculated up NO2 356 356 356 356 356 356 356 calc DMEXA Reading up NH3 28 364 461 703 971 1200 100608b E 4.2.9
Deduced ammonia up SUM-NOx 27 259 349 553 795 1015 calc A-C=F
MEXA down SUM 579 449 471 600 869 1121 100608b2 G 4.2.9MEXA down NO 208 148 149 149 152 100608d H 4.2.9
MEXA Reading down NH3 14 42.9 169 333 625 836 100608b2 I 4.2.9NH3 + NO2 down SUM-NO 371 323 451 720 969 calc G-H=J
NH3 + NOx consumed up - down SUM-SUM 13 375 443 518 491 459 calc A-G=K
4% gas 1 SCR0 40 50 60 75 100 120
592 824 914 1118 1360 1580 ANH3 27 259 349 553 795 1015 F
up - down, 1SCR SUM-SUM 1SCR 13 375 443 518 491 459 K
up - down,4% 1SCR NOx or NH3 consumed 6.5 188 222 259 246 230 K/2=L
up - down,4% 1SCR NO consumed 1 50 61 60 60 57 B-H=M
up - down,4% 1SCR NO2 consumed 5.5 138 161 199 186 173 L-M=N
concentration table NH3 up 0 40 50 60 75 100 120Deduced ammonia up 1SCR SUM-NOx 27 259 349 553 795 1015 F
NH3 21 72 128 294 550 786 F-L
NOx 559 378 344 306 320 336 C-L
NO 208 159 148 149 149 152 B-M
NO2 351 219 196 157 171 184 D-N
Downstream
Chapter 4 Experimental Results and Discussions
92
Figure 4.3 Summary of measurement with 1 and 4 SCR bricks.
From figure 4.3, it is observed that the 5% gas tests were performed at low ammonia input to avoid
excessive ammonia slip. The spray tests were completed at high potential ammonia input levels due
to the spray unit being intended for heavy duty application but it was used at its lower range setting
for this investigation. The 4% gas tests on the 1 SCR brick covered the entire range. Unfortunately
the 4% gas tests did not investigate 4 SCRs.
4.4 Analysis of spray compared to gas
From figure 4.3 the 4 SCR test results for 5% gas (o-marker) matched fairly the spray results (x-
marker) at around 500 to 600 ppm ammonia input. The 1 SCR test results for NO shows good
agreement between 4% gas (∆), 5% gas (o) and urea spray (x). The NO2 and NH3 level after one SCR
with spray shows higher values and do not agree with the 4% gas results. The reason for this is
because droplets from urea spray are able to survive through one brick and this is not accounted for
in the methodology applied in this investigation. It is unlikely that HNCO will survive passage through
1 SCR bricks as hydrolysis is rapid.
-50
50
150
250
350
450
550
650
0 200 400 600 800 1000 1200
Amou
nt o
f Spe
cies
Con
sum
ed, p
pm
Ammonia upstream ("Potential" for spray), ppm
Summary of 4%(^) 5%(O) & spray(X)1SCR 5% NOx or NH3
4SCR 5% NOx or NH3
1SCR 5% NO
4SCR 5% NO
1SCR 5% NO2
4SCR 5% NO2
1SCR spray NOx or NH3
4SCR spray NOx or NH3
1SCR spray NO
4SCR spray NO
1SCR spray NO2
4SCR spray NO2
4% 1SCR NOx or NH3
4% 1SCR NO
4% 1SCR NO2
Chapter 4 Experimental Results and Discussions
93
The differences between the one SCR spray and 4% gas can be utilised to deduce how much NH3
exits from one SCR brick in droplet (i.e. non-gaseous ammonia) form. This is considered as one of the
most significant finding in the investigation and will be discussed later.
4.5 Analysis of droplet behaviour.
In this section the analysis of ammonia released from the urea spray is discussed. Section 4.5.1
discusses ammonia release from urea spray upstream of the SCR for both 1 SCR and 4 SCR cases.
Section 4.5.2 discusses ammonia released within the 4 SCR bricks. Finally section 4.5.3 discusses
ammonia passing through the 1 SCR brick in droplet form.
4.5.1 Ammonia released from urea spray upstream of the SCR bricks.
In order to analyse the droplet behaviour upstream of the SCR, the information from potential
ammonia from the spray (see appendix 4.1.5) and the deduced ammonia from the upstream
measurements of 1 SCR and 4 SCR bricks are used (see table 4.1.5 and 4.1.6). This information is
plotted against the potential ammonia input from the spray in figure 4.5.1.
Figure 4.5.1 Ammonia released from spray upstream of the SCR bricks
From figure 4.5.1, it is observed that from half to three quarters of the droplets from the urea spray
remained in droplet form, or possibly as HNCO at the inlet of the first SCR bricks. This is obtained
from deduction of the potential ammonia upstream to the deduced ammonia upstream of the brick.
The 1 SCR and 4 SCR results vary due to experimental variation. The SUM values represent a series of
experiments performed at various times using the same method.
0
200
400
600
800
1000
1200
500 600 700 800 900 1000 1100
ppm
Potential NH3 input from spray, ppm
Ammonia in spray experiments - Release of NH3 upstream of SCR bricks Potential ups 1SCR
Pot NH3
Potential ups 4SCR Pot NH3
Deduced ammonia ups 1SCR SUM-NOxDeduced ammonia ups 4SCR SUM-NOxAmmonia ups 1SCR retained as dropsAmmonia ups 4SCR retained as drops
Chapter 4 Experimental Results and Discussions
94
4.5.2 Ammonia released from urea spray within the 4 SCR bricks
In order to analyse this, the measurements of ammonia gas entering and consumed in the 4 SCR
brick are needed. Figure 4.5.2 shows the ammonia released from the spray within the 4 SCR bricks.
Figure 4.5.2 Ammonia released from urea spray within 4 SCR bricks.
From figure 4.5.2, the differences between the ammonia consumed by the 4 SCR and the ammonia
released upstream of the 4 SCR gives the ammonia released within the 4 SCR bricks. It is observed
that approximately 200 ppm or less ammonia is being released within the bricks to be consumed by
the SCR reactions. It also shows that, as the spray injection flow rates increases, the ammonia
released within the bricks reduced possibly as a result of lower brick temperatures. This is probably
due to the excess spray cooling the SCR bricks.
4.5.3 Ammonia passing through 1 SCR brick in droplets form.
In this analysis, the results from NOx or NH3 consumed within the 1 SCR brick for the spray and 4%
gas are compared. Based on the differences between the two results, the ammonia that passes
through 1 SCR brick in the form of droplets can be found. This plot is shown in figure 4.5.3.
0
250
500
750
400 500 600 700 800 900 1000 1100
Amm
onia
, ppm
Potential ammonia input, ppm
Ammonia released from spray within 4 SCR bricks
NH3 consumed in 4 SCR
NH3 gas ups 4 SCR
NH3 release in 4 SCRs
Chapter 4 Experimental Results and Discussions
95
Figure 4.5.3 Ammonia passing through 1 SCR brick in droplets form.
It is observed from the differences that approximately 10 to 100 ppm of potential ammonia from the
urea spray did pass through the 1 SCR brick. The information shown here also indicates, more
droplets passing through as the urea flow rate increased.
4.6 Analysis of NO and NO2 conversion efficiency and ammonia slip.
Three significant parameters in SCR system are NO, NO2 conversion efficiency and ammonia slip. The
analysis of NO and NO2 conversion efficiency requires the NO and NO2 inlet condition and the exit
NO, NO2 measurements. From the summary of data only five sets of results (see table 4.1.5, 4.1.6,
4.2.5, 4.2.8 and 4.2.9) can be analysed for NO and NO2 conversion efficiency. Two sets of result are
from the 1 SCR and 4 SCR spray, another two from 1 SCR and 4 SCR with 5% gas and one set from 1
SCR with 4% gas
0
100
200
300
400
500
400 600 800 1000 1200
Amou
nt o
f Spe
cies
Con
sum
ed, p
pm
Ammonia upstream ("Potential" for spray)
Ammonia passing through 1 SCR brick in dropletSpray & 1SCR;Nox or NH3 consumed (value too big)
4% gas & 1SCR; Nox or NH3 consumed (value correct)
Difference -> NH3 that passes thru 1SCR as drops
Chapter 4 Experimental Results and Discussions
96
4.6.1 NO conversion efficiency
In this section the NO conversion efficiency can be plotted against the calculated potential ammonia
input from the spray, 4% gas and 5% gas with respect to the SCR brick length as shown in figure
4.6.1. NO conversion efficiency can be defined as below:
𝑁𝑂 𝑐𝑜𝑛𝑣𝑒𝑟𝑠𝑖𝑜𝑛 𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 = 𝑁𝑂 𝑖𝑛 − 𝑁𝑂 𝑜𝑢𝑡
𝑁𝑂 𝑖𝑛× 100%
From figure 4.6.1, the excessive urea spray setting only results in a NO conversion of approximately
30 % for the 1 SCR brick (shown in red and blue). The reason for this is due to the high space velocity
(low residence time) of around 182k/hour for the 1 SCR brick at a temperature in the region of 590K.
As a result of the high space velocity, unconverted droplets can survive through the SCR brick
unreacted. The 1 SCR with spray and 4% gas shows a perfect match of NO conversion from around
400 to 1100 ppm ammonia input while the 5% gas shows NO conversion slightly higher for lower
range of ammonia input (less than 500 ppm).
Figure 4.6.1 NO conversion with respect to SCR length.
0%
20%
40%
60%
80%
100%
0 200 400 600 800 1000 1200 1400
NO
con
vers
ion
Ammonia input (ppm)
NO conversion efficiency
4SCR 5% gas
4SCR spray
1SCR 5% gas
1SCR spray
1SCR 4% gas
Chapter 4 Experimental Results and Discussions
97
In contrast, the 4 SCR brick conversion efficiency was very high and close to 100% when ammonia
input was sufficient (shown in green and purple). The space velocity for 4 SCR is reasonably low at
around 45.5 k/hour, which gives higher residence time of the ammonia in the SCR bricks. The SCR
bricks space velocity at approximately 590 K is summarized in table 4.6.1
Table 4.6.1 Space velocity for SCR bricks used in the investigation.
Number of SCR brick
Brick Length, mm
Space Velocity, k/hour
1 91 182
2 182 91
3 273 61
4 364 45.5
4.6.2 NO2 conversion efficiency
Similarly the NO2 conversion efficiency was performed with the results from 1 and 4 SCR with urea
spray, 1 and 4 SCR with 5% gas and 1 SCR with 4% gas. The NO2 conversion efficiency is shown in
figure 4.6.2
The NO2 conversion efficiency is defined using the following equation:
𝑁𝑂2 𝑐𝑜𝑛𝑣𝑒𝑟𝑠𝑖𝑜𝑛 𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑐𝑦 = 𝑁𝑂2 𝑖𝑛 − 𝑁𝑂2 𝑜𝑢𝑡
𝑁𝑂2 𝑖𝑛× 100%
The conversion efficiency for the 1 SCR spray case is too high based on the assumption that all
droplets are converted within the bricks. The conversion efficiency for 4 SCR spray is over 100%
based on the negative NO2 out (table 4.1.6) due to experimental error.
Chapter 4 Experimental Results and Discussions
98
Figure 4.6.2 NO2 conversion with respect to SCR brick length.
The NO2 conversion was higher for the 4 SCR spray (purple) and 4 SCR 5% gas (in green) followed by
the 1 SCR spray (red). The 4 SCR 5% gas efficiency increased linearly from 0 to reach 100% at
ammonia input of 500 ppm. The NO2 efficiency for 4 SCR spray ranged from 80 to 100% and reached
the peak at ammonia input of 700 ppm. The 4% gas with 1 SCR NO2 conversion shows slightly higher
conversion as compared to the 5% with 1 SCR. The NO2 conversion efficiency for 1 SCR spray is also
higher from 70 to 90% as compared to 40 to 55% for 1 SCR 4% (blue) and below 45% for 1 SCR 5%
(yellow). Even with the high space velocity in the 1 SCR spray case, the NO2 reaches up to 90%
conversion. This will be discussed further in the following section.
4.6.3 Comparison of NO and NO2 conversion.
To summarize the NO and NO2 conversion efficiency for along the SCR length, the results from the
previous two sections are plotted together in figure 4.6.3 Dashed lines show NO2 conversion and
solid lines show NO conversion. The 4 SCR is shown with symbol (∆) and the 1 SCR with symbol (□)
in the legend.
0%
20%
40%
60%
80%
100%
120%
0 200 400 600 800 1000 1200 1400
NO
2co
nver
sion
Ammonia input (ppm)
NO2 conversion efficiency
4SCR 5% gas
4SCR spray
1SCR spray
1SCR 4% gas
1SCR 5% gas
Chapter 4 Experimental Results and Discussions
99
Figure 4.6.3 Comparison of NO and NO2 conversion efficiency
Comparing the NO and NO2 conversion efficiency for the 4 SCR bricks (purple and green lines) shows
NO2 conversion efficiency for the spray and gas were similar in all test cases as compared with the
NO. However for 1 SCR brick NO2 conversion, the 4% gas (blue-dash line) and the spray (red-dash
line) are much higher than the NO conversion. The spray NO2 conversion (red- dashed line) is high
due to droplets passing through unaccounted for, as discussed earlier. The 5% gas results (in yellow),
however at low ammonia input are closer but by 500 ppm ammonia input, again the NO2 conversion
exceed the NO conversion.
This is considered as one of the most significant finding in this study. Whilst, NO2 and NO react at
equal amount with NH3 for the fast kinetic scheme reviewed earlier (equation2.1e in section 2.1),
this contradicts with findings from the NO, NO2 conversion observed in the studies here where NO2
conversion level are significantly higher than NO after 1 SCR brick.
4.6.4 Ammonia slip.
High concentration of ammonia released from the spray poses another problem associated with
ammonia slip. At the time of this investigation, the actual NH3 slip measurement could not be
performed due to the interference problem with the MEXA analyser as previously discussed.
However, the methodology described in this thesis allows the ammonia slip to be deduced as
summarized in table of results (refer to table 4.1.5, 4.1.6, 4.2.5, 4.2.6, 4.2.7, 4.2.8 and 4.2.9) earlier.
0%
20%
40%
60%
80%
100%
120%
0 200 400 600 800 1000 1200 1400
NO
, N
O2
conv
ersio
n
Ammonia input (ppm)
NO, NO2 conversion efficiency
1SCR spray NO
1SCR spray NO2
1SCR 4% gas NO
1SCR 4% gas NO2
1SCR 5% gas NO
1SCR 5% gas NO2
4SCR spray NO
4SCR spray NO2
4SCR 5% gas NO
4SCR 5% gas NO2
Chapter 4 Experimental Results and Discussions
100
The highest ammonia slips are from the 1 SCR brick clearly due to the high space velocity, see figure
4.6.4. The 4 SCR spray also gives high ammonia slippage due to the excess spray used. However the
slippage for both spray cases are too high because it include droplet. The 4 SCR spray study shows
slip because excess potential ammonia, > 550 ppm, was supplied. For 1 SCR brick, the difference
between the spray and 4% gas gives the amount of ammonia slippage in droplet form (shown in
orange).The 2, 3 and 4 SCR with 5% gas produced almost no slippage clearly due to most of the
supplied ammonia having reacted with the engine out NOx up to supplied ammonia input levels of
500 ppm.
Figure 4.6.4 Ammonia slip against potential ammonia input with respect to SCR brick length.
4.7 CFD modelling analysis comparison with measurements.
CFD simulations were performed to compare with the results for 1 and 4 SCR with 5% gas. Only the 1
SCR data was available for the 4% gas. The CFD package Star-CD version 3.26 was used and all of the
CFD modelling results were presented and compared with the experimental data from this study in
the published paper (Tamaldin et al. 2010). The CFD work described here was undertaken by Dr.
C.A. Roberts following discussions regarding inlet boundary conditions derived from the
experiments. In some cases, experiments were repeated to recheck data and to supply additional
information for the CFD model.
-50
50
150
250
350
450
550
650
750
850
0 200 400 600 800 1000 1200
Amm
onia
slip
(ppm
)
Ammonia input (potential for spray) (ppm)
Ammonia slip
1 SCR 4% gas
1SCR spray
4SCR spray
1 SCR 5% gas
2SCR 5% gas
3SCR 5% gas
4 SCR 5% gas
droplet slip
Chapter 4 Experimental Results and Discussions
101
4.7.1 CFD data comparison with ammonia gas injection for 1 SCR and 4 SCR bricks.
In this analysis, the data from 1 SCR and 4 SCR with the 4% and 5% gas are plotted against the
ammonia input separately. For the 1 SCR with 4% and 5% gas, the results for NO and NO2 + NH3 are
plotted against the inlet ammonia. The CFD and measurement results are compared as shown in
figure 4.7.1a.
Figure 4.7.1a CFD and data comparison for species level at exit from 1 SCR brick.
Direct comparison of NO and NH3+ NO2 measurements at the exit of the SCR bricks for 4% and 5%
gas with CFD result are shown. At low level ammonia input, approximately less than 400 ppm, CFD
and measurement match reasonably. At higher ammonia input level, above 400 ppm CFD and
measurement do not acceptably match. A similar comparison was performed with the 4 SCR bricks
shown in figure 4.7.1b. The results for NO and NH3+ NO2 at the exit of the 4 SCR bricks is plotted
against ammonia input.
Figure 4.7.1b CFD and data comparison for species levels at exit from 4 SCR bricks.
Chapter 4 Experimental Results and Discussions
102
Similar to the 1 SCR result, the agreement between CFD and measurement for 4 SCR bricks is fairly
good at low ammonia input, approximately less than 500 ppm. The NO level measured and the CFD
for 4 SCR matched much better than the 1 SCR comparison. At high ammonia input, greater than 500
ppm CFD prediction and measurement deviate for NH3 + NO2.
4.8 Comparison of CFD prediction with NO2, NO and NH3 at the SCR exit.
The final analysis involves comparison of the exhaust species at exit from the SCR bricks. For this
analysis, three different cases will be discussed and presented separately. Results are plotted with
respect to the individual level of NH3 gas injected.
4.8.1 CFD prediction comparison of NO2 with measurement results.
Measurement and CFD simulation are plotted against SCR brick length. CFD prediction and
measurement for NO2 exiting the SCR bricks is shown in figure 4.8.1. The legend described the
ammonia input used. In this comparison, it is observed that fairly good agreement between
simulation and measurements is achieved after one SCR brick. Past the two SCR bricks agreement is
poorer.
Figure 4.8.1 Simulations of NO2 against measurements at SCR exit.
Chapter 4 Experimental Results and Discussions
103
4.8.2 CFD prediction comparison of NO with measurement results.
CFD prediction and measurement comparison for NO exiting the SCR bricks is shown in figure
4.8.2.The NO results comparison to simulation shows good agreement after two bricks but poorly
agree after the one SCR brick. Similarly the experimental and CFD ammonia input are shown in the
legend.
Figure 4.8.2 Simulations of NO against measurements at SCR exit.
4.8.3 CFD prediction comparison of NH3 with measurement results.
CFD prediction and measurement for NH3 exiting the SCR bricks is shown in figure 4.8.3. The most
significant observation from the NH3 simulation is the NH3 slip predicted after the two bricks but not
observed in the measurements. Ammonia input for the experiments and CFD are shown in the
legend.
Chapter 4 Experimental Results and Discussions
104
Figure 4.8.3 Simulations of NH3 against measurements at SCR exit.
4.8.4 Overall remark from CFD comparison with measurements.
Generally the agreement between the comparisons of CFD prediction to the measurements is fairly
good. Measurements showed that reactions were complete after two SCR bricks. The kinetic scheme
applied in this simulation was based on the kinetic presented by Olsson et al, 2008. However, it is
not known how similar the catalysts used in Olsson are to those of this investigation. Some changes
were made to the total ammonia storage capacity suitable for the catalysts used in these
experiments. Thus, good overall agreement was achieved even simulation do not show full
agreement with the model.
Chapter 4 Experimental Results and Discussions
105
4.9 Transient analysis in the investigation.
In this investigation transient behaviour of the NOx reduction SCR reaction with urea spray or ammonia
gas injection was observed. The transient behaviour observed was slightly different when using urea
spray as compared with ammonia gas.
4.9.1 Transient analysis of 4 SCR bricks with 4% NH3 gas.
This was a 4% NH3 gas study with 4 SCR bricks. NOx at a level of 611 ppm from the engine as measured
by EXSA, 557 ppm as measured by MEXA, was supplied to the SCR. NH3 gas was injected at input level of
1045 ppm at approximately 900 seconds. The NOx readings were completely reduced when the
ammonia gas injection started, with no ammonia slip present despite excess ammonia injected. This can
be seen in time between 900 to 1100 seconds in the figure 4.9.1
Figure 4.9.1 Sample of transient response in 4 SCR bricks with 4% NH3 gas.
mxNOx 557 ppm
exNOx 611 ppm,
0
200
400
600
800
1000
0 500 1000 1500 2000 2500 3000
ppm
time (secs)
Transient test case - 4 SCR with 4% NH3 gas Refn(9jun08)
NH3 ppm
mxNOx ppm
exNOx ppm
NH3 gas injection
Chapter 4 Experimental Results and Discussions
106
Part of the ammonia trace for the 4 SCR brick with 4% gas is shown again in figure 4.9.1a. On this figure
the area is separated into three regions. Region A represents the reacted NH3. Region B describes the
ammonia storage or absorption of the SCR bricks and region C represents the ammonia slipped at the
back of the 4 SCR bricks.
Figure 4.9.1a Transient Analysis for 4% gas with 4 SCR
The NOx out level initially was 557.3 ppm before the ammonia gas injection started and it rapidly
dropped to zero as soon as ammonia gas was injected. The NOx level remains zero from the beginning of
the 4% ammonia gas injection until the end of the trace because it was reacting with the excess
ammonia supplied. The ammonia gas injection setting used in this region was calculated to be 1045
ppm.
The total NH3 reacted is matched by the amount of NOx reacted and can be found using the following;
Area for region A = Total NH3 reacted = (1045.3 - 488) ppm x 753 seconds
= 419 647 ppm.secs ≈ 7.02 grams*Note
220
0
100
200
300
400
500
600
700
800
900
1000
1100
1200
0 100 200 300 400 500 600 700 800 900
ppm
time (secs)
Transient Analysis - 4 SCR with 4% NH3 gas Refn(9jun08)
NH3 ppm
mxNOx ppm
4% gas injection
NH3 out 488
A - NH3 Reacted
B - NH3 StoredC - NH3 Slipped
NH3 input 1045.3
A - NH3 Reacted
B - NH3 StoredC - NH3 Slipped
379
308
753
NOx 557.3
Chapter 4 Experimental Results and Discussions
107
*Note :
To convert an area in NH3 ppm.s to a mass in grams.
Multiply by 17
28.96 × 28.5
1000 000= 0.00001673
Where 17 is the Molecular weight for NH3 and
28.96 is Molecular weight for exhaust.
28.5 is exhaust mass flow rate in grams/seconds
Area of B + C = 488 ppm x 753 seconds
= 367 464 ppm.secs ≈ 6.15 grams
Although excess ammonia was supplied the slip remains zero for a period of 220 seconds until it begins
to emerge at the back of the 4 SCR. During this period, the ammonia is continuously reacting with NOx
but it has also been stored in the 4 SCR bricks. Then, when the ammonia storage within the 4 SCR bricks
approached its maximum capacity, the surplus ammonia started to exit the bricks at about 220 seconds.
Region C starts as the ammonia slip begins to rise after the 220 seconds. As suggested by Olsson et al.
(2007) as the maximum storage capacity is reached, the ammonia desorption will occur at a rate faster
than the ammonia absorption of the bricks. This effect together with the continuous 4% ammonia gas
injection caused the ammonia slip to rise exponentially until a steady value was reached, in this case,
ammonia slip at 488 ppm. At this stage, the excess ammonia supplied to the bricks just passed through
because there was no NOx to react and no free storage capacity. The area above the ammonia slippage
line until maximum ammonia slippage at 488 ppm will give the ammonia storage of the bricks.
The time taken to reach the steady value of ammonia slip was approximately 533 seconds from the
onset of slip. The area under the ammonia slip curve can be found by integrating the curve within the
220 to 753 seconds time period. This can be achieved numerically within an excel spreadsheet as shown
in appendix 4.9.1a. The area was converted to mass and found to be around 3.14 grams slipped
between 220 to 753 seconds.
Chapter 4 Experimental Results and Discussions
108
Finally the ammonia stored which is represented by the area of Region B,
Stored ammonia = (Area of B + C) – NH3 slip (Region C)
= (6.15– 3.14) grams
≈ 3.01 grams
Ammonia Stored in the 4 SCR bricks ≈ 3.01 grams
The ammonia reacted was found to be 7.02 grams a further 3.01 grams was stored while 3.14 grams
slipped at the back.
4.9.1.1 Time constants for gas.
The time constant for NOx falling from its initial value (557.3 ppm) in figure 4.9.1a can be found from the
falling curve. Starting from the NOx reading of 557.3 ppm, it dropped rapidly as soon as ammonia gas at
4% was injected. The time constant for this reaction could be found as the following, defining the fall to
36.79% as the time constant.
[C] = 0.3679 [C]o
[C] = 0.3679 [557.3 ppm] = 205 ppm
time at 205 ppm = 5 seconds
The time constant for NOx falling was about 5 seconds.
This time constant is mainly from the time response of the MEXA analyzer. The chemical reactions
themselves are very much faster.
The time constant for ammonia rising during the slip is found at 63.3 % of the final steady value. In this
case it was found that time taken was approximately 159 seconds for NH3 to rise to 308 ppm.
Chapter 4 Experimental Results and Discussions
109
4.9.2 Transient analysis of 4 SCR brick with urea spray
The transient analysis was performed on the 4 SCR with urea spray in a similar way to the transient
analysis for 4 SCR with 4% NH3 gas. An example of a typical transient observation with urea spray and 4
SCR is shown in figure 4.9.2. In this case, the spray setting was adjusted and the incoming ammonia was
estimated at around 929, then 857 and then 785 ppm. The spray was potentially capable of supplying
more ammonia than this but some remained as urea droplets and was not available for reaction. From
the figure shown, the incoming NOx was 539 ppm throughout and this was fully reacted as there was no
NOx slip detected at the exit of the SCR. The trace up to 956 seconds can be divided into three different
regions.
Figure 4.9.2 Transient Analysis for urea spray with 4 SCR
Region A, represents the overall NH3 reacted. The area under region A starts from the first urea spray
injection and the spray rate changed twice until time reached 956 seconds. In this region, all of the
incoming NOx at 539 ppm was reacted. The ammonia slip was observed just after the 270 seconds. The
total NH3 reacted in this case can be found using;
mNOx 539
150 270
NH3 246
0
100
200
300
400
500
600
700
800
900
1000
0 200 400 600 800 1000 1200
ppm
time(sec)
Transient Analysis 4 SCR with SprayRefn 230708b(L1)
NH3mNOxSpray trigger
956509
246
A - NH3 Reacted
B - NH3 Stored
C - NH3 Slipped
30 spray setting (ms)34 32
929
857
785
390
318
Chapter 4 Experimental Results and Discussions
110
Area for region A = Total NH3 reacted = 539 ppm x 956 seconds
= 515 284 ppm.secs
≈ 8.62 grams
Area for region B + C
= (390 x 150) + 318(270-150) + 246(956-270)
= 265 416 ppm.secs
≈ 4.44 grams
Region B represents the amount of ammonia being stored by the 4 SCR bricks. The ammonia slip started
rising around 270 seconds. It took another 686 seconds to reach the ammonia slip steady value of 246
ppm.
Region C represents the ammonia slipped at the exit of the 4 SCR bricks. The steady value of 246 ppm is
reached at about 956 seconds. The amount of ammonia slippage can be found by integration of the area
under ammonia slip curve between 270 to 956 seconds. This is obtained using numerical integration in
excel spreadsheet and converted to mass as shown in appendix 4.9.2a. The amount of ammonia slip was
calculated and found to be 1.93 grams.
Similarly to the 4% ammonia gas study, at 270 seconds ammonia storage is approaching its maximum
and ammonia desorption started. This is clearly shown by the exponential rise in the ammonia slip curve
in figure 4.9.2.
Finally the ammonia stored under Region B = Area (B+C) – Area C
= 4.44 – 1.93 grams
Ammonia Stored in the 4 SCR bricks ≈ 2.5 grams
The total ammonia reacted in the SCR system was found to be 8.62 grams, 2.5 grams was stored in the
bricks while 1.93 grams slip at the back.
Chapter 4 Experimental Results and Discussions
111
4.9.2.1 Time constants for urea spray.
The time constant for NOx reduction in this case is defined as the time where the concentration has
fallen 0.3679 from its initial value.
[C] = 0.3679 [C]o
[C] = 0.3679 [539 ppm] = 198.3 ppm
Time @198.3 ppm = 7.5 seconds
Therefore time constant for NOx reduction is 7.5 seconds. However, this time constant is dominated by
the time response from the MEXA analyzer since the NOx and NH3 reaction in the SCR is occurring at a
much faster rate.
The time constant for the ammonia rise is the time from where the ammonia slip just begins until 0.632
of its final steady value as described in the rising curve analysis. Therefore the time constant for
ammonia rise in this case is as follows:
NH3 begin slip @ after 270 seconds
0.632 x 246 ppm = 155.5 ppm@509 seconds
Time constant for ammonia rise = 509 – 270 = 239 seconds.
4.9.3 Comparison of the urea spray and ammonia gas transients.
In order to compare the transient behaviour of the gas with the urea spray study, the results from
sections 4.9.1 and 4.9.2 are compared. The summary of comparison between the two cases is shown in
table 4.9.3.
Chapter 4 Experimental Results and Discussions
112
Table 4.9.3 Comparison of the 4% gas with urea spray transient analysis.
Properties 4% gas with
4 SCR bricks
Urea spray with
4 SCR bricks
1. NOx reduction time constant. 5 seconds 7.5 seconds
2. Ammonia storage time to onset of slip. 220 seconds 270 seconds
3. Time constant of rise in ammonia slip 159 seconds 239 seconds
4. Amount of ammonia reacted 7.02 grams 8.62 grams
5. Amount of ammonia stored 3.01 grams 2.50 grams
6. Amount of ammonia slipped 3.14 grams 1.93 grams
From the table 4.9.3, it was observed that the NOx reduction time constant for gas is slightly less than
the urea spray case, but both times were attributable to the response time of MEXA analyser and should
be instantaneous. The ammonia storage, rise and slip times were different with 4 % gas as compared
with urea spray. In urea spray case droplet conversion is necessary while the 4% gas is readily available
for SCR reaction. The amount of stored and slipped are slightly higher with 4% gas case compared with
the urea spray case.
4.10 Summary of the experimental and simulation results.
This investigation has compared the performance of SCR system with urea spray injection and ammonia
gas. These studies involved the NO2/NO ratio of approximately 60/40 and shows all reactions with
ammonia were complete after the two SCR bricks at a length of 182 mm.
To summarize the results the following concluding remarks could be made:
• Some precaution and concern is needed when interpretations are made based on
measurements reading from a CLD based analyser involving NO and NO2.This is needed
especially in the present of ammonia. The methodology suggested in this investigation however
enables amount consumed to be extracted. From known amounts of input from individual
measurements upstream and downstream of the SCR, the data for NO, NO2 and NH3 can be
extracted.
Chapter 4 Experimental Results and Discussions
113
• In the urea spray studies, when the urea in the form of AdBlue solution was injected, about 200
ppm of NH3 were released from the droplets of urea spray and reacting with NOx within the SCR
bricks.
• From estimation, it was observed that in the range of 10 to 100 ppm of potential ammonia
manage to pass through one SCR at a length of 91 mm in droplets form.
• From the CFD simulations using the porous medium approach and kinetics scheme published in
the open literature, have shown some ability to predict the steady state tests investigated here.
• The model has been used to predict individual species along the SCR bricks length and some
moderate agreement with the measurement has been achieved especially with the long bricks.
For short brick, space velocity was high and there were breakthrough of all species.
• A transient analysis showed that the time constant for NOx reduction are quite close for gas and
spray but for the time constant for ammonia slip is higher in spray than gas.
• NO2 conversion efficiency was found higher than NO in all test cases which contradict with fast
reaction kinetic.
Chapter 5 Conclusions and Future Work
114
CHAPTER 5: CONCLUSIONS AND FUTURE WORK
5.0 Conclusions and Future work: Introduction.
Despite the limitations of the MEXA gas analyser, and the need to derive a strategy for
interpretation of the measurements made by it, a thorough investigation of SCR process has been
made in a specially designed exhaust system on an experimental test bed. The conclusion from the
investigation include the development of the experimental techniques, the interference of NO2 and
NH3, the methodology, the transient response, the SCR and spray system performance and the
significance of the main findings from the result chapter.
5.1 DPF-DOC Arrangement.
The DOC-DPF arrangement was tested for NO2 to NO ratio to assist the SCR reactions. With this
arrangement, the NO coming out from the engine was oxidized by the DOC but later reacted with
the trapped soot in the DPF, leaving less NO2 out than before. With less NO2, the SCR reactions
taking place were at the minimal level and leaving NOx out passing the system still at higher
readings. In the final arrangement used in this investigation, DPF-DOC was identified as the
acceptable sequence upstream of the SCR. Utilizing this arrangement, higher NO2 to NO ratio was
achieved. In the literature, 50:50 NO2 to NO ratio or higher was shown as the preferred condition to
optimize the SCR reactions. Subsequently, in this investigation, a higher NO2 to NO ratio was studied.
5.2 Experimental techniques.
The biggest obstacles in the beginning of this investigation were to establish suitable experimental
techniques in order to complete the steady state study with the SCR system. Interferences within
the analysers were a particular problem because the continuous injection of the urea or ammonia
gas was necessary in this investigation. The use of both urea spray and ammonia gas were
investigated. Interference and reaction between NO2 and NH3 on the NOx converter within the
MEXA has resulted in significant loss of reliable directly measured test data.
This was overcome by a methodology that allowed all required parameters to be deduced. The spray
used in this study was designed for heavy-duty application with the lowest possible setting utilized.
This caused intermittent problems especially with the low settings involved in light duty
Chapter 5 Conclusions and Future Work
115
investigation. Due to the formation of white deposit (polymeric complexes such as melamine,
ammelide and ammeline) spray blockage can occur and hinder SCR catalyst performance as
described by Fang et al. 2003. Therefore a rigorous procedure for spray monitoring and cleaning was
incorporated to ensure the spray was working properly in the experiment. All of the challenges and
obstacles were overcome to develop a methodology for obtaining reliable data in this study.
5.3 Behaviour of urea droplet from spray.
One of the important findings with the spray test cases, was the proportion of urea droplet
decomposed before entering the SCR brick for NOx reduction reaction to occur. This detail was
described in section 4.5 of the results chapter. It shows that more than half of the actual ammonia
was still in the droplet form upstream of the SCR brick. It was observed approximately around 200
ppm ammonia was released from the droplet in the first SCR bricks and consumed for the NOx
reduction reactions. The final finding shows between 10 -100 ppm of potential ammonia passed
through the first brick as droplets under circumstances from NOx matched spray input to excess
spray.
5.4 Space Velocity and Resident Time Effect.
The SCR space velocity role for the NOx reduction efficiency was a very important observation in this
investigation. The variation of space velocity had immediate effect on the residence time of the
exhaust gases and ammonia within the SCR. It was found that, the 2, 3 and 4 SCR bricks had a similar
effect on the SCR reactions taking place. All the NOx reduction had apparently completed in the 2
SCR bricks, therefore in the results shown for 4 SCR bricks could be assumed similar to the 2 SCR
bricks. Conversion was incomplete in 1 SCR but it was notable that NO2 conversion was greater than
NO conversion. This is significant finding because it cannot be explained by the fast SCR reaction
acting alone.
5.5 Transient observation and storage.
Transient response observation during NOx reduction and ammonia slippage also reveals about the
ammonia absorption by the SCR bricks. The amount of NH3 stored was about 3 grams on 4 SCR bricks
for both gas and spray cases as described earlier in section 4.9.3.
Chapter 5 Conclusions and Future Work
116
5.6 Significant of findings in chapter 4
• NOx and NH3 reaction were completed after the 2 SCR bricks.
• The 2, 3 and 4 SCR bricks show similar NOx or NH3 consumed.
• Meticulous cleaning of the urea spray was necessary for well-controlled operation.
• The gas and the spray results were similar in both 1 and 4 SCR bricks.
• With 1 SCR spray, droplets were passing through unconverted.
• Repeatability with gas test cases was excellent.
• Droplet released ammonia more at the SCR sites rather than upstream of the SCR.
• Droplet converted to ammonia much better in 4 SCR than 1 SCR.
• For 1 SCR cases, after about 400 ppm NH3 consume, no further NOx reduction was taking
place.
• Agreement overall was fairly good although predicted NH3 slip after two bricks was not
observed in the experiments. Agreement for NO was good after 2 SCR bricks but not good
after 1 SCR brick. NO2 agreement was better after 1 SCR brick then 2 SCR bricks.
• Transient response of the spray and gas cases was studied and provided measured values of
NH3 storage.
• NO2 conversion was higher than NO for 1 SCR brick which does not agree with fast SCR
kinetics suggest other reaction occurred.
Overall urea spray results showed similar trends to the ammonia gas results. The 5% ammonia gas
results covered the lower range of ammonia gas used and the urea spray injected higher ammonia.
This can clearly be seen section 4.4.2 comparison of all NOx and NH3 consumed. The NOx or NH3
consumed from the 1 SCR test with spray closely matched the 1 SCR test with gas. The 4 SCR test
with the spray matched as the continuation of the 4 SCR test with gas line.
5.7 Contributions to the knowledge
• Measurement of NO2 in the presence of high concentrations of NH3 is clearly erroneous due to
interference effect using the MEXA CLD based analyser. Despite this problem, a unique
methodology was developed in this thesis to extract useful information to describe the SCR
reaction in this investigation.
Chapter 5 Conclusions and Future Work
117
• The comparative analysis of the investigation with the use of urea spray and ammonia gas was
described and lead to NO and NO2 conversion efficiency with the use of different SCR bricks
length.
• Insight into the behaviour of the urea droplets in the investigation was obtained. It show that
from half to three quarter of droplet from spray remained unconverted to ammonia gas at the
entry of first SCR brick. About 200 ppm ammonia released from droplet react in the SCR brick
and between 10 to 100 ppm of potential ammonia passed through the first bricks as droplets.
This occurs from the conditions of NOx matched spray input to excess spray.
• The CFD model for gas provide reasonable predictions for the long bricks while the short brick
shows breakthrough of all species due to high space velocity. The reaction kinetics used from
literature was able to show some ability to describe the species profiles within the SCR bricks.
• The most significant findings in this study is the higher NO2 conversion efficiency for 1 SCR brick
compared to NO. This cannot be described by the fast SCR kinetic scheme.
5.8 Recommendation for Future Work.
Throughout the investigations, many areas have been identified for future work in order to optimise
the SCR system working in the real application. Some of the identified areas include the exhaust gas
analyser, dosing system, more robust spray design, spray position and angle into the exhaust stream,
reduced length of the SCR system and also the transient study with the SCR.
5.8.1 Improved gas analyser to measure NOx in presence of ammonia.
Most of the time spent in this investigation involved trying to obtain reliable measurements of NOx,
NO and NH3 upstream and downstream of the SCR brick. The CLD based analyser clearly causes a lot
of setback in this investigation and variations in the results. A FTIR (Fourier Transfer Infra Red) based
analyser was recently identified as better candidates for investigation with the use of urea and
ammonia of this magnitude. The response time of the analyser was crucial in getting this information
as the phase changes of the species within the exhaust gases need to be fully captured.
Chapter 5 Conclusions and Future Work
118
5.8.2 Spray Dosing System.
Ideally a closed loop feedback spray dosing system would be desirable for this investigation. A
manual over-ride system also need to be incorporated, taking into consideration of cold start
condition. The system integrated with the engine ECU unit is under heavy development by many
automotive suppliers for this purpose.
5.8.3 Cleaning of spray or continuous spraying
To avoid having to clean the spray injector, a more robust spray design is needed to suit the light
duty application. Continuous spraying into the exhaust would definitely not be appropriate, but
should be covered by the closed loop feedback spray dosing system mention earlier. As for the
cleaning, perhaps the solution for this lies with the concentration of urea solution used or a better
designed spray to avoid any deposit build up.
5.8.4 Improved warm up and system using sequential program.
The control software for the engine test bed is capable of programming of the sequence for setting
up the engine warm up and cool down period, calibrating the analyser, periodic parameters logging
and many other task. As the investigations were conducted, very limited time was spent on this side
of the program due to other difficulties and challenges faced with the analyser and the spray system.
The analysers control from the test bed program was not configured for this investigation. In the
future, this should be seriously considered to have better control and monitoring sequence.
5.8.5 Signal trigger improvement with level differentiation of spray pulses and gas settings.
Current spray and gas injection system was manually control by adjusting the signal generator for
the spray and the gas flow meter for the gas. The spray signal generator was also connected as a
voltage input to the engine test bed data logger. As for the logging the gas flow into the main engine
test bed program, was done manually by pressing the trigger switch when the gas started.
For improvement of this system, the spray or gas injection system should have a signal input to the
main engine data logger. Therefore, every spray sequence should be seen in the result plot similar to
the exhaust gas data showing when the injector started and by how much is being injected.
Chapter 5 Conclusions and Future Work
119
5.8.6 Investigation of Effect of Spray Angle and Positions.
In this investigation, only the generic position of the spray is being explored which is upstream of the
SCR brick into the expansion chamber for proper mixing. Other possibility was not explored such as
spraying into a narrow pipe close to the SCR brick. The spray position and angle into the exhaust
should be investigated to further improve this system. As in the real application, the effect of spray
angle is crucial due to the confined spaces and angle existing in the real exhaust system in a light
duty vehicle.
5.8.7 Moving from 1D to 3D flow (change from long cone to short cone after the spray)
As previously described in the methodology section 3.2.6 a long cone diffuser after the expansion
chamber was used to ensure uniform single dimensional flow of the exhaust gas mixed with the
ammonia entering the SCR brick. In the future, this long diffuser cone could be replaced with a short
diffuser cone which would be closer in geometry to a real system. This changes the flow from single
dimensional to three dimensional flow, therefore a more complex CFD model would be required for
this case.
5.8.8 Transient study (acceleration and deceleration)
This study only considered very simple transient but future transient study with the SCR system
would be necessary. As the engine going through the series of acceleration and deceleration as
prescribed in the European Transient Cycle (ETC), the SCR performance results would be highly
valuable.
5.8.9 Engine Mass flow rate measurement and logging.
The engine mass flow rate measurement in this investigation was conducted using external Ricardo
mass flow meter as described in section 3.1.3 and manual data was logged from the digital
manometer. Ideally, this information should be directly logged from the engine ECU either with the
use of engine management system such as Gredi and dSpace. Getting information logged to the
engine data logger would improve the experimental procedure for this type of investigation in the
future.
120
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Nejar, N. and Illan-Gomez, M.J. (2007) - Potassium-Copper and Potassium-Cobalt Catalysts supported on Alumina for Simultaneous NOx and Soot Removal from Simulated Diesel Engine Exhaust, Applied Catalysis B: Environmental, Vol. 70, Issue 1-4, pp261-268.
146
Nobukawa, T., Sugawara, K., Okumura, K., Tomishige, K. and Kunimori, K. (2007) - Role of Active Oxygen Transients in Selective Catalytic Reduction of N2O with CH4 over Fe-Zeolite Catalysts, Applied Catalysis B: Environmental, Vol. 70, Issue 1-4, pp342-352.
147
Nojima, S., Iida, K., Kobayashi, N. and Naito, O. (2001) - Development of NOx Removal SCR Catalyst for Low SO2 Oxidation, Technical Review - Mitsubishi Heavy Industries, Vol.38, Issue 2, pp87-91.
148
Nova, I., Ciardelli, C., Tronconi, E., Chatterjee, D. and Bandl-Konrad, B. (2006) - NH3-SCR of NO over a V-based Catalyst: Low-T Redox Kinetics with NH3 Inhibition, AIChE Journal, Vol.52, Issue 9, pp3222-3233.
149
Nova, I., Ciardelli, C., Tronconi, E., Chatterjee, D. and Bandl-Konrad, B. (2006) - NH3- NO/NO2 Chemistry over V-based Catalysts and its Role in the Mechanism of the Fast SCR Reaction, Catalysis Today, Vol.114, Issue 1, pp3-12.
150
Nova, I., Lietti, L., Tronconi, E. and Forzatti, P. (2000) - Dynamics of SCR reaction over a TiO2-Supported Vanadia-Tungsta Commercial Catalyst, Catalysis Today, Vol. 60, Issue 1, pp73-82.
151
Nova, I., Lietti, L., Tronconi, E. and Forzatti, P. (2001) - Transient Response Method Applied to the Kinetic Analysis of the DeNOx-SCR Reaction, Chemical Engineering Science, Vol. 56, Issue 4, pp1229-1237.
152
Nova, I., Lietti, L., Tronconi, E., Forzatti, P., Avelino Corma, F.V.M.S.M. and José Luis,G.F.(2000) - Concentration Programmed Adsorption-Desorption/Surface Reaction Study of the SCR-DeNOx Reaction, Studies in Surface Science and Catalysis, pp623-628.
130
153
OEHHA, (2005) - Chemicals Known To The State To Cause Cancer Or Reproductive Toxicity, California Environmental Protection Agency, Office of Environmental Health Hazard Assessment (OEHHA), Safe Drinking Water and Toxic Enforcement Act of 1986 (Proposition 65), Updated May 27, 2005.
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Olsson, L., Sjövall, H. and Blint, R.J. (2008) - A Kinetic Model for Ammonia Selective Catalytic Reduction over Cu-ZSM-5, Applied Catalysis B: Environmental, Vol. 81, Issue 3-4, pp203-217.
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Pieterse, J.A.Z. and Booneveld, S. (2007) - Catalytic reduction of NOx with H2/CO/CH4 over PdMOR Catalysts, Applied Catalysis B: Environmental, Vol.73, Issue 3-4, pp327-335.
157
Pieterse, J.A.Z., Top, H., Vollink, F., Hoving, K. and van den Brink, R.W. (2006) - Selective Catalytic Reduction of NOx in Real Exhaust Gas of Gas Engines Using Unburned Gas: Catalyst Deactivation and Advances Toward Long-Term Stability, Chemical Engineering Journal, Vol.120, Issue 1-2, pp17-23.
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Qi, G. and Yang, R.T. (2005) - Low-Temperature SCR of NO with NH3 over Noble Metal Promoted Fe-ZSM-5 Catalysts, Catalysis Letters, Vol. 100, Issue 3-4, pp 243-246.
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Reuters News Services (2007) - European Carmakers Reduced Carbon Dioxide (CO2) Emissions from New Cars by only 0.2 percent in 2006, Far Off an Agreed Goal, Brussels September 2007, Available online, http://www.planetark.com/dailynewsstory.cfm/newsid/44167/story.htm
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Schmeig, S.J., Lee, J-H.(2005) - Evaluation of Supplier Catalyst Formulations for the SCR of NOx with Ammonia, SAE 2005-01-3881, Powertrain and Fluid Systems Conference and Exhibition San Antonio, Texas, October 24-27, 2005.
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164
Shibata, J., Hashimoto, M., Shimizu, K.-I., Yoshida, H., Hattori, T. and Satsuma, A. (2004) - Factors Controlling Activity and Selectivity for SCR of NO by Hydrogen over Supported Platinum Catalysts, Journal of Physical Chemistry B, Vol.108, Issue 47, pp18327-18335.
165 Snyder, J. D., Subramaniam, B.(1998) - Numerical Simulation of a Reverse flow NOx-SCR Reactor with Side Stream Ammonia Addition, Chem Eng Sci Vol. 53, Issue 4, pp727-734.
166
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167
Spurk (2000) US EPA-United States, Environmental Protection Agency, - Federal and California Exhaust and Evaporative Emission Standards for Light-Duty Vehicles and Light-Duty Trucks, Document No: EPA420-B-00-001, February 2000.
131
168 Spurk, D.C., Pfeifer, M., Gieshoff, J, Lox, E. (2001) - Ein SCR Katalysator auch fuer denEnsatz im PKW,10 Aachener Kolloquium Fazu.(translated)- A SCR Catalyst for the use in Passenger Cars, 10th Aachen Colloqium on Automobile and Engine Technology 2001.
169
Spurk, P.C., M. Pfeifer, et al., (2007) – Challenges for the Future Diesel Engines Exhaust Gas Aftertreatment System, SAE2007-01-0040, Fuels & Emission Conference, Cape Town, South Africa, January 23-25, 2007
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Sullivan, J.A. and Keane, O. (2007) - A Combination of NOx Trapping Materials and Urea- SCR Catalysts for use in the Removal of NOx from Mobile Diesel Engines, Applied Catalysis B: Environmental, Vol. 70, Issue 1-4, pp205-214.
171
Sullivan, J.A., Doherty, J. A., (2005) - NH3 and Urea in the Selective Catalytic Reduction of NOx over Oxide-Supported Copper Catalysts, Applied Catalysis B: Environmental, 10 February 2005, Vol. 55, Issue 3, pp185-194.
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Summers, J.C., Van Houtte, S. and Psaras, D. (1996) - Simultaneous control of particulate and NOx Emissions from Diesel Engines, Applied Catalysis B: Environmental, Vol.10, Issue 1-3, pp139-156.
173
Suzuki, H. and Ishii, H. (2006) - Emission Characteristics of a Urea SCR System Under Catalyst Activated and De-activated Conditions, Review of Automotive Engineering, Vol. 27, Issue 2, pp223-228.
174
Takada, K., Kusaka, J., Daisho, Y. (2007) - Empirical and Numerical Study of the Improvements in NOx Reduction by a Urea-SCR System Attainable by Controlling the Relative Proportions of NO and NO2, Review of Automotive Engineering, JSAE Technical paper 4-28-1-41.
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176
Tang, X., Hao, J., Xu, W. and Li, J. (2007) - Low Temperature Selective Catalytic Reduction of NOx with NH3 over Amorphous MnOx Catalysts Prepared by Three Methods, Catalysis Communications, Vol. 8, Issue 3, pp329-334.
177 Tatur, M. (2009) - Solid SCR Demonstration Truck Application, presentation at US Department of Energy Directions in Engine Efficiency and Emissions Research (DEER) conference, Dearbon, Michigan, August 2009.
178
Technical Report of MECA-Manufacturers of Emissions Controls Association,(1999) - The Effect of Sulfur in Diesel Fuel on Catalyst, Emission Control Technology.
179
Tennison, P., Lambert, C., Levin, M.(2004) - NOx control development with urea SCR on a Diesel Passenger Car,SAE 2004-01-1291, SAE 2004 World Congress and Exhibition, Detroit Michigan, March 8-11, 2004
180 Theis, J.R. (2009) - SCR Catalyst Systems Optimized for Light-off and Steady State Performance, SAE2009-01-0901, SAE 2009 World Congress, Detroit, Michigan, April 20-23, 2009.
181
Theis, J.R. and Gulari, E. Estimating the temperatures of the NOx storage sites in a lean NOx trap during oxidation reactions. Applied Catalysis B: Environmental, In Press, Corrected Proof, 300.
132
182
Thompson, J., Beeck, J.D., Joubert, E.,Wilhelm, T. (2008) - Case studies of urea SCR Integration on Passenger Cars;Monitoring of Urea Inside the Tank During Hot and Cold Environment Test Missions, SAE 2008-01-1181, SAE 2008 World Congress, Detroit, Michigan, April 14-17, 2008.
183
Tomita, A., Yoshii, T., Teranishi, S., Nagao, M. and Hibino, T. (2007) - Selective catalytic Reduction of NOx by H2 Using Proton Conductors as Catalyst Supports, Journal of Catalysis, Vol. 247, Issue 2, pp137-144.
184
Tranconi, E, Nova, I., Ciardelli, C. et al., (2005) - Modelling of an SCR Catalytic Converter for Diesel Exhaust After Treatment:Dynamics Effects at Low Temperature, Catalysis Today, 15 August 2005, Vol.105, pp 529 - 536,
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186
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187 Twigg, M.V. (2007) - Progress and Future Challenges in Controlling Automotive Exhaust Gas Emissions, Applied Catalysis B: Environmental, Vol. 70, Issue 1-4, pp2-15.
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189
United States, Environmental Protection Agency (2006) - Certification Procedure for Light- Duty and Heavy Duty Diesel Vehicle Using Selective Catalyst Reduction (SCR) Technologies, Doc no: EPA-HQ-OAR-2006-0886-0002.pdf
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134
APPENDICES
A-1
Appendix 3.1.1 – Power curve for Ford 2.0 litre diesel engine (complementary of Ford powertrain development division, 2001
y = 0.607xR2 = 0.993
0.00
10.00
20.00
30.00
40.00
50.00
60.00
70.00
80.00
90.00
100.00
110.00
0 10 20 30 40 50 60 70 80 90 100 110 120 130 140 150 160 170 180
Pressure Head (mm of water)
MF
R (
g/s)
ExperimentalTheoretical data from ricardoLinear (Experimental)
Appendix 3.1.3 - Ricardo Mass flow meter calibration chart.
A-2
A-3
Appendix 3.2 Supplied parts for SCR exhaust build.
No Parts Description Quantity Size
1 Flange 20 pcs 125 x 80 mm Centre hole 50 mm diameter
2 Flange Cover 4 pcs 115 x 85 mm
3 Hex bolts 100 pcs 10 mm diameter
4 Nuts 100 pcs 10 mm inside diameter
5 Washer 200 pcs 11 mm inside diameter
6 Ring Flange 20 pcs
Diameter outDiameter
=190 mm in
8 x11mm holes =115mm
7 Gasket – 2 hole 20 pcs 125 x 80 mm Centre hole 50 mm diameter
8 Gasket – 8 hole 20 pcs
Diameter outDiameter
=190 mm in
8 x11mm holes =115mm
9 Inlet cone 1 unit
Diameter smallDiameter
=50 mm large
Length = 150 mm = 115 mm
10 2nd 1 unit cone
Diameter smallDiameter
=50 mm large
Length = 900 mm = 115 mm
11
Expansion duct/ 3rd
cone 1 unit
Diameter smallDiameter
=50 mm large
Length = 410 mm = 115 mm
12 Exit cone / 4th cone 1 unit
Diameter smallDiameter
=50 mm large
Length = 90 mm = 115 mm
13 DOC Assembly 3 unit 1 unit 95 mm length 2 unit 190 mm length
14 DPF Assembly 1 unit 155 mm length
15 SCR Assembly 3 unit 1 unit 92.5 mm length 2 unit 185 mm length
16 Flexible hose 1 unit 50 mm x 1 m length
17 Straight pipe 1 unit 50 mm x 2m length
18
Expansion box assembly
1 unit
Refer to drawing in appendix 3.2b
A-4
Appendix 3.2b List of drawing for
SCR Exhaust System
1 - Exhaust Manifold exit
2 - Flexi hose assembly
3 -1st
4 - DPF Assembly
cone 150 mm
5 - DOC Assembly
6 - Instrumentation module assembly – 110 mm
7 - 2nd
8 - Expansion box assembly
cone – 90 mm
9 - Instrumentation pipe assembly – 200 mm
10 - 3rd
11 - SCR assembly
cone – 410 mm
12 - Instrumentation module assembly – 90 mm
13 - Last cone assembly
14 - T-piece assembly
15 - Final assembly front view
16 - Final assembly isometric view
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mm09 yssa eludom tsni
B
C
D
1 2
A
321 4
B
A
5 6
C
4A
NWARD
D'KHC
D'VPPA
GFM
A.Q
:DEIFICEPS ESIWREHTO SSELNUSRETEMILLIM NI ERA SNOISNEMID
:HSINIF ECAFRUS:SECNARELOT
:RAENIL :RALUGNA
:HSINIF DNA RUBED PRAHS KAERB
SEGDE
EMAN ERUTANGIS ETAD
:LAIRETAM
GNIWARD ELACS TON OD NOISIVER
:ELTIT
.ON GWD
3:1:ELACS 1 FO 1 TEEHS
ydneF
63.85
63.85
091
511
11
511
0905
09
:THGIEW
yssa enoc tsal
B
C
D
1 2
A
321 4
B
A
5 6
C
4A
NWARD
D'KHC
D'VPPA
GFM
A.Q
:DEIFICEPS ESIWREHTO SSELNUSRETEMILLIM NI ERA SNOISNEMID
:HSINIF ECAFRUS:SECNARELOT
:RAENIL :RALUGNA
:HSINIF DNA RUBED PRAHS KAERB
SEGDE
EMAN ERUTANGIS ETAD
:LAIRETAM
GNIWARD ELACS TON OD NOISIVER
:ELTIT
.ON GWD
5.2:1:ELACS 1 FO 1 TEEHS
ydneF
59
59
01
05
521
08
01
711
01
°09
:THGIEW
yssa eceip t
B
C
D
1 2
A
321 4
B
A
5 6
C
4A
NWARD
D'KHC
D'VPPA
GFM
A.Q
:DEIFICEPS ESIWREHTO SSELNUSRETEMILLIM NI ERA SNOISNEMID
:HSINIF ECAFRUS:SECNARELOT
:RAENIL :RALUGNA
:HSINIF DNA RUBED PRAHS KAERB
SEGDE
EMAN ERUTANGIS ETAD
:LAIRETAM
GNIWARD ELACS TON OD NOISIVER
:ELTIT
.ON GWD
3:1:ELACS 1 FO 1 TEEHS
noitatnemurtsnieludom
58.7303 mm
ydneF
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weiv tnorf yssa laniF
B
C
D
1 2
A
321 4
B
A
5 6
C
4A
NWARD
D'KHC
D'VPPA
GFM
A.Q
:DEIFICEPS ESIWREHTO SSELNUSRETEMILLIM NI ERA SNOISNEMID
:HSINIF ECAFRUS:SECNARELOT
:RAENIL :RALUGNA
:HSINIF DNA RUBED PRAHS KAERB
SEGDE
EMAN ERUTANGIS ETAD
:LAIRETAM
GNIWARD ELACS TON OD NOISIVER
:ELTIT
.ON GWD
05:1:ELACS 1 FO 1 TEEHS
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A.Q
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:RAENIL :RALUGNA
:HSINIF DNA RUBED PRAHS KAERB
SEGDE
EMAN ERUTANGIS ETAD
:LAIRETAM
GNIWARD ELACS TON OD NOISIVER
:ELTIT
.ON GWD
05:1:ELACS 1 FO 1 TEEHS
FPD
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A-5
Appendix 3.4.1 MEXA 1170Nx Ammonia Analyser Specifications
a. Analyser Outline
b. Optional
c. System configuration
A-5a
d. Analyser performance
A-5b
Appendix 3.5: Lambda Sensor Connection Configuration
At the back of LA4 Unit
LA4 Power supply
Lambda sensor power supply
A-6
A-7
Appendix 3.6.2 Potential Ammonia Released from Urea Spray Calculation
Calculation of Potential amount of ammonia introduced into exhaust system by urea spray
The disintegration of urea to form ammonia takes place in two stages. First the urea disintegrates at about 137O
CO(NH
C to form ammonia and iso-cyanic acid. Then the iso-cyanic acid is hydrolysed to produce ammonia.
2)2 NHCO + NH
HNCO + H
3
2O NH3 + CO
The net effect is that for every mol of urea, two mols of ammonia are produced.
2
In the experiments described in this thesis, a typical exhaust mass flow rate was 28.5 g/s. An assumption may be made that the mol weight of exhaust is 28.96, the same value as for air. Hence, the rate of exhaust flow may be expressed as 0.984 mol/s.
The spray was calibrated with water. It is assumed that the spray system moves the same volume of aqueous urea as of water. The specific gravity of 32.5% by weight aqueous urea solution is about 1.09. Hence, the spray system flow rate of urea is higher than for water.
The table below shows Calculation of Potential Ammonia level in exhaust from spray flow rate.
Spray pulse
length (ms)
flow rate of water
from calibration
(mg/s)
Flow rate of urea
(mg/s) water
x1.09
Flow rate of urea 32.5% by weight
(mg/s) fr urea x
32.5%
urea 60g/mol flow rate (mol/s)
1/60.06*1
6.30/1000
urea in 0.984 mol/s exhaust flow (ppm) 0.000271/0.984116
*1 000 000
Potential ammonia (ppm) 1 mol urea = 2
mol ammonia,=2
x 275.6996
24 46 50.1 16.3 0.000271 276 552
26 51 55.6 18.1 0.000301 307 614
* 28 58 63.2 20.5 0.000342 348 696
30 68 74.1 24.1 0.000401 409 818
32 74 80.7 26.2 0.000436 444 888
34 80 87.2 28.3 0.000472 480 960
36 87 94.8 30.8 0.000513 521 1042
40 92 100.3 32.6 0.000543 551 1102
*Note: The recommended working range for spray injector was from 28 ms upward. Any setting below 28 ms would work intermittently.
A-8
Appendix 3.7a Calibration chart for NH3 gas flow rate using Glass float
A-9
Appendix 3.7b Calibration chart for NH3 gas flow rate using Stainless Steel float
Appendix 3.7.1 Summary of gas flow rate with 4% and 5% ammonia in N2
A-10
Calculation of gas flow rate with 4% & 5% ammonia in N2 with steel & glass float
Gas Mol wt (g)Sp gravity (SG gas) Cal Factor
Air 28.96 1.00 1.004% ammonia 27.56 0.9517 1.0255% ammonia 27.45 0.948 1.027
if Tgas > 301 K (28 C) changes must be made to avoid error more than 1%Pgas >1 bar(14.7psi)Pgas = 1.5 psi 5% errorPgas = 3 psi 10 % error
Pg = gas pressure in flow meter (psi absolute)Tg = gas temperature in flow meter (degree absolute) assume 300 K tempSG = Specific gravity of gas
4% Steel Floatsteel psi calib chart pressure correction corrected l/min PPM
0 0.0 0 0.000 0 016 0.1 4 1.003 4.11 12440 0.3 10 1.010 10.35 31150 0.5 13 1.017 13.55 40660 1.0 16 1.033 16.94 50675 2.0 20 1.066 21.85 650100 3.0 28 1.097 31.48 930120 4.0 34 1.128 39.31 1155
4% Glass FloatGlass psi calib chart pressure correction corrected l/min PPM
0 0.0 0.0 0.000 0 016 0.1 2.0 1.003 2.06 6240 0.3 5.4 1.010 5.59 16850 0.4 6.7 1.014 6.96 20960 0.5 8.5 1.017 8.86 26775 0.7 10.8 1.023 11.32 340100 1.0 15.0 1.033 15.88 475120 1.3 18.0 1.043 19.24 574
5% Glass FloatGlass psi calib chart pressure correction corrected l/min PPM
0 0.0 0.0 0.000 0.00 016 0.1 2.0 1.003 2.06 7332 0.2 4.1 1.007 4.24 14948 0.4 6.5 1.014 6.77 23860 0.5 8.2 1.017 8.56 30080 0.7 11.5 1.024 12.09 42396 1.0 13.9 1.033 14.75 515
SGTgPgFactorCAL××
×=7.14
294_
Appendix 3.7.1a Calculation of gas flow rate with 4% ammonia in N2 with steel float
A-11
Calculation of gas flow rate with 4% ammonia in N2 with steel float
Gas Mol wt (g)Sp gravity (SG gas) Cal Factor
Air 28.96 1.00 1.004% ammon 27.56 0.9517 1.0255% ammon 27.45 0.948 1.027
if Tgas > 301 K (28 C) changes must be made to avoid error more than 1%Pgas >1 bar(14.7psi)Pgas = 1.5 psi 5% errorPgas = 3 psi 10 % error
Pg = gas pressure in flow meter (psi absolute)Tg = gas temperature in flow meter (degree absolute) assume 300 K tempSG = Specific gravity of gas
4% Steel Float assume temp. 294 K
steel psi calib chart abs P+psipressure
correctionabs
correctioncorrected
l/mincorreted flow rate PPM
4% m3/s0 0.00 0.0 0.0 0 0 0 0.000000 016 0.10 4.0 14.8 1.003 1.025 4.11 0.000069 12440 0.30 10.0 15.0 1.010 1.025 10.35 0.000173 31150 0.50 13.0 15.2 1.017 1.025 13.55 0.000226 40660 1.00 16.0 15.7 1.033 1.025 16.95 0.000282 50675 2.00 20.0 16.7 1.066 1.025 21.85 0.000364 650
100 3.00 28.0 17.7 1.097 1.025 31.49 0.000525 930120 4.00 34.0 18.7 1.128 1.025 39.31 0.000655 1155
correted flow rate
Flow rate NH3 in 4%
mix
o occupies
0.0224 m3 @294 K
o ate o injected mixture
(NH3+N2)
ot o ate in exhaust
incl injected gas
Ammonia level
m3/s m3/s mol/s mol/s mol/s ppm0.000000 0.0000000 0.000000 0.00000 0.984 00.000069 0.0000027 0.000122 0.00306 0.987 1240.000173 0.0000069 0.000308 0.00770 0.992 3110.000226 0.0000090 0.000403 0.01008 0.994 4060.000282 0.0000113 0.000504 0.01261 0.997 5060.000364 0.0000146 0.000650 0.01626 1.000 6500.000525 0.0000210 0.000937 0.02343 1.007 9300.000655 0.0000262 0.001170 0.02925 1.013 1155
SGTgPg
FactorCAL××
×=
7.14294
_
Sample calculation:For Steel float at 120 & 4 psiReading from Calibration chart is 34.0 litre/minAssume flowing gas mixture temperature ~ 294 Kso no temperature correction is needed.
Corrected flow rate is 34 x 1.128 x 1.025 = 39.31 liter/min = 0.655 litre/s = 0.000655 m3/s
Flow rate of ammonia (4% in mixture) = 0.04 x 0.000655 = 0.0000262 m3/s
Assume 1 mol of ammonia occupies 22.4 litres = 0.0224 m3 at 273 KCorrecting fo temperature 1 mol occupies 0.0240 m3 at 293 K
Thus Ammonia flow rate is 0.0000262/0.0224 = 0.00117 mol/s
Flow rate of injected mixture (ammonia + N2 ) is (100/4) x 0.001170 mol/s = 0.02925 mol/s
The engine exhaust flow rate is 28.5 g/s = 28.5/28.96 mol/s = 0.984 mol/s
Total flow rate is exhaust including injected gas = 0.984 + 0.029 = 1.013 mol/s
Ammonia level = 1 000 000 x (mol/s NH3) / (mol/s exhaust) = 0.001170 / 1.013 * 1 000 000 = 1155 ppm
Appendix 3.7.1b Calculation of gas flow rate with 4% ammonia in N2 with glass float
A-12
Calculation of gas flow rate with 4% ammonia in N2 with glass float
Gas Mol wt (g)Sp gravity (SG
gas) Cal FactorAir 28.96 1.00 1.00
4% ammoni 27.56 0.9517 1.0255% ammoni 27.45 0.948 1.027
if Tgas > 301 K (28 C) changes must be made to avoid error more than 1%Pgas >1 bar(14.7psi)Pgas = 1.5 psi 5% errorPgas = 3 psi 10 % error
Pg = gas pressure in flow meter (psi absolute)Tg = gas temperature in flow meter (degree absolute) assume 300 K tempSG = Specific gravity of gas
4% Glass Float assume temp. 294 K
Glass psi calib chart abs P+psipressure
correctionabs
correctioncorrected
l/mincorreted flow rate PPM
4% m3/s0 0.00 0.0 0.0 0 0 0 0 0
16 0.10 2.0 14.8 1.003 1.025 2.06 0.000034 6240 0.30 5.4 15.0 1.010 1.025 5.59 0.000093 16850 0.40 6.7 15.1 1.014 1.025 6.96 0.000116 20960 0.50 8.5 15.2 1.017 1.025 8.86 0.000148 26775 0.67 10.8 15.4 1.023 1.025 11.32 0.000189 340100 1.00 15.0 15.7 1.033 1.025 15.89 0.000265 475120 1.30 18.0 16.0 1.043 1.025 19.25 0.000321 574
correted flow rate
Flow rate NH3 in 4%
mix
1 mol occupies 0.0224 m3 @294
K
Flow rate of injected mixture
(NH3+N2)
Tot flow rate in exhaust
incl injected gas
Ammonia level
m3/s m3/s mol/s mol/s mol/s ppm0.000000 0.0000000 0.000000 0.00000 0.984 00.000034 0.0000014 0.000061 0.00152 0.986 620.000093 0.0000037 0.000166 0.00415 0.988 1680.000116 0.0000046 0.000207 0.00518 0.989 2090.000148 0.0000059 0.000264 0.00661 0.991 2670.000189 0.0000076 0.000338 0.00844 0.992 3400.000265 0.0000106 0.000473 0.01183 0.996 4750.000321 0.0000128 0.000573 0.01433 0.998 574
SGTgPgFactorCAL××
×=
7.14294_
Sample calculation:For Glass float at 120 & 1.3 psiReading from Calibration chart is 18.0 litre/minAssume flowing gas mixture temperature ~ 294 Kso no temperature correction is needed.
Corrected flow rate is 18 x 1.043 x 1.025 = 19.25 liter/min = 0.321 litre/s = 0.000321 m3/s
Flow rate of ammonia (4% in mixture) = 0.04 x 0.000321 = 0.0000128 m3/s
Assume 1 mol of ammonia occupies 22.4 litres = 0.0224 m3 at 273 KCorrecting fo temperature 1 mol occupies 0.0240 m3 at 293 K
Thus Ammonia flow rate is 0.0000123/0.0224 = 0.000573 mol/s
Flow rate of injected mixture (ammonia + N2 ) is (100/4) x 0.000573 mol/s = 0.01433 mol/s
The engine exhaust flow rate is 28.5 g/s = 28.5/28.96 mol/s = 0.984 mol/s
Total flow rate is exhaust including injected gas = 0.984 + 0.01433 = 0.998 mol/s
Ammonia level = 1 000 000 x (mol/s NH3) / (mol/s exhaust) = 0.000573 / 0.998 * 1 000 000 = 574 ppm
Appendix 3.7.1c Calculation of gas flow rate with 5% ammonia in N2 with glass float
A-13
Calculation of gas flow rate with 5 % ammonia in N2 with glass float
Gas Mol wt (g)Sp gravity (SG
gas) Cal FactorAir 28.96 1.00 1.00
4% ammoni 27.56 0.9517 1.0255% ammoni 27.45 0.948 1.027
if Tgas > 301 K (28 C) changes must be made to avoid error more than 1%Pgas >1 bar(14.7psi)Pgas = 1.5 psi 5% errorPgas = 3 psi 10 % error
Pg = gas pressure in flow meter (psi absolute)Tg = gas temperature in flow meter (degree absolute)SG = Specific gravity of gas
5% Glass Float assume temp. 294 K
Glass psi calib chart abs P+psipressure
correctionabs
correctioncorrected
l/mincorreted flow
rate PPM5%0 0 0 0 0 0 0 0.000000 0
16 0.1 2 14.8 1.003 1.027 2.06 0.000034 7332 0.2 4.1 14.9 1.007 1.027 4.24 0.000071 14948 0.4 6.5 15.1 1.014 1.027 6.77 0.000113 23860 0.5 8.2 15.2 1.017 1.027 8.56 0.000143 30080 0.7 11.5 15.4 1.024 1.027 12.09 0.000201 42396 1.0 13.9 15.7 1.033 1.027 14.75 0.000246 515
corrected flow rate
Flow rate NH3 in 5%
mix
1 mol occupies 0.0240 m3 @294 K
Flow rate of injected mixture
Tot flow rate in exhaust incl injected gas
Ammonia level
m3/s m3/s mol/s mol/s mol/s ppm0.000000 0.0000000 0.0000000 0.00000 0.984 00.000034 0.0000017 0.0000716 0.00143 0.985 730.000071 0.0000035 0.0001472 0.00294 0.987 1490.000113 0.0000056 0.0002349 0.00470 0.989 2380.000143 0.0000071 0.0002973 0.00595 0.990 3000.000201 0.0000101 0.0004197 0.00839 0.992 4230.000246 0.0000123 0.0005123 0.01025 0.994 515
SGTgPgFactorCAL××
×=
7.14294_
Sample calculation:For Glass float at 96 & 1.0 psiReading from Calibration chart is 13.9 litre/minAssume flowing gas mixture temperature ~ 294 Kso no temperature correction is needed.
Corrected flow rate is 13.9 x 1.033 x 1.027 = 14.75 liter/min = 0.246 litre/s = 0.000246 m3/s
Flow rate of ammonia (5% in mixture) = 0.05 x 0.000246 = 0.0000123 m3/s
Assume 1 mol of ammonia occupies 22.4 litres = 0.0224 m3 at 273 KCorrecting fo temperature 1 mol occupies 0.0240 m3 at 293 K
Thus Ammonia flow rate is 0.0000123/0.024 = 0.000513 miol/s
Flow rate of injected mixture (ammonia + N2 ) is (100/5) x 0.0005123 mol/s = 0.01025 mol/s
The engine exhaust flow rate is 28.5 g/s = 28.5/28.96 mol/s = 0.984 mol/s
Total flow rate is exhaust including injected gas = 0.984 + 0.010 = 0.994 mol/s
Ammonia level = (mol/s NH3) / (mol/s exhaust) x 1 000 000 = 0.0005123 / 0.994 x 1 000 000 = 515 ppm
A-14
0
100
200
300
400
500
600
700
800
900
1000
1100
1200
0 10 20 30 40 50 60 70 80 90 100 110 120 130
PPM
Urea Spray & Gas flow setting
Appendix 3.10.4d Gas flow setting/ Spray setting vs. Ammonia level produced
Glass 5%
steel 4%
Glass 4%
Spray
Appendix 3.7.1d Gas and Spray setting vs. Ammonia produced
B-1
4.0 - List of appendices for Chapter 4 : Experimental Results
Appendix 4.1.5 Experimental data for
Date: (3, 7, 9 July 2008)
Urea Spray: 1 SCR
0700708a NO2
090708c NH
upstream & downstream 1 SCR no spray
3
070708b NO
upstream 1 SCR R
2
090708b NH
downstream 1 SCR
3
downstream 1 SCR L
Appendix 4.1.5b SUM in and SUM out average for
150708c NH
1 SCR with spray
3
150708c NH
upstream 1 SCR L
3
090708c NH
upstream 1 SCR R
3
090708c NH
upstream 1 SCR L
3
070708d NH
upstream 1 SCR R
3
upstream 1 SCR
150708b NH3
150708b NH
downstream 1 SCR Left
3
090708b NH
downstream 1 SCR Right
3
090708b NH
downstream 1 SCR L
3
070708c NH
downstream 1 SCR R
3
downstream 1 SCR
B-1a
Appendix 4.1.6 Experimental data for Urea Spray: 4 SCR
Date: (1, 7,18,23,24 July 2008)
240708b NO2
240708b NH
up 4 SCR L-R with spray
3
020708c NO
upstream 4 SCR L1-R1-L1
2
230708b NH
downstream 4 SCR with spray
3
downstream 4 SCR R1
Appendix 4.1.6b SUM in and SUM out average for
180708c NH
4 SCR with spray
3
240708b NH
upstream 4 SCR spray 34-24 L-R
3
240708b NH
upstream 4 SCR spray L
3
upstream 4 SCR spray R
180708b NH3
230708b NH
downstream 4 SCR L - R
3
downstream 4 SCR L-R
Appendix 4.2.5 Experimental data for 5% NH3 gas: 1 SCR
Date: (5%gas 12, 21 august 2008)
120808b NH3
120808c NH
upstream 1 SCR 5% gas
3
210808c NO downstream 1 SCR 5% gas
downstream 1 SCR 5% gas
210208 NO downstream 1 SCR 5%-manual log in log book (Appendix 4.2.5b)
B-1b
Appendix 4.2.6 Experimental data for NH3
Date:(11 august 2008)
gas: 2 SCR
110808b NH3
110808c NH
upstream 2 SCR 5% gas
3
210808c NO downstream 1 SCR 5% gas
downstream 2 SCR 5% gas
Appendix 4.2.7 Experimental data for NH3
Date:(7 august 2008)
gas: 3 SCR
070808b NH3
070808c NH
upstream 3 SCR 5% gas
3
downstream 3 SCR 5% gas
Appendix 4.2.8 Experimental data for NH3
Date:(16, 25 jun2008 & 5, 6 august 2008)
gas: 4 SCR
060808b NH3
060808e NH
upstream 4 SCR 5% gas
3
060808c NO
downstream 4 SCR 5% gas
2
060808d NO
upstream 4 SCR 5% gas
2
downstream 4 SCR 5% gas
Appendix 4.2.9 Experimental data for 4% NH3
Date:(Trial 4% 10, 11,12,16,24 jun08/final5%gas 12, 21 august 2008)
gas: 1 SCR
100608b NH3
100608c NO upstream 1 SCR 4% gas
upstream 1 SCR 4% gas
100608b NH3
100608d NO
downstream 1 SCR 4% gas
2
downstream 1 SCR 4% gas
Appendix 4.1.5 Experimental data for Urea Spray: 1 SCR
Dates: (3, 7, 9 July 2008)
0700708a NO2
090708c NH
upstream & downstream 1 SCR no spray
3
070708b NO
upstream 1 SCR R
2
090708b NH
downstream 1 SCR
3
downstream 1 SCR L
Appendix 4.1.5b SUM in and SUM out average for 1 SCR with spray
150708c NH3
150708c NH
upstream 1 SCR L
3
090708c NH
upstream 1 SCR R
3
090708c NH
upstream 1 SCR L
3
070708d NH
upstream 1 SCR R
3
upstream 1 SCR
150708b NH3
150708b NH
downstream 1 SCR Left
3
090708b NH
downstream 1 SCR Right
3
090708b NH
downstream 1 SCR L
3
070708c NH
downstream 1 SCR R
3
downstream 1 SCR
B-2
mNOx up dw 536
NO up, 196
NO dw, 191
NO2 up345
NO2 dw 346
0
100
200
300
400
500
600
700
800
900
1000
0 10 20 30 40 50 60 70 80
ppm
time(min)
7jul08a NO2 up & down 1scr no spray
exsa NOx calc ppm
mexa SUM calc ppm
mexa NOx calc ppm
mexa NH3 calc ppm
NDIR spray trigger V
Mexa cal
NO2 up 1scr NO2 down 1scr
mSUM 541
mSUM 540
mSUM , 785757
750 730704
685650
mNOx , 420 mexa NOx , 422
mexa NOx , 425
mexa NOx ,430
mexa NOx 435
mexa Nox 442
mexa NOx 445
mexa NH3 360NH3 330
NH3 315NH3 290
NH3 270NH3 245
NH3 210150
250
350
450
550
650
750
850
4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
ppm
time(min)
09jul08c NH3 up 1scr spray 36, 34, 32, 30, 28, 26, 24 L
eNOx ppm
mSUM
mNOx
mNH3
spray V
36 242628303234
sprayoff
mSUM540
eNOx, 570
NOx 542
mNOx , 258 mNOx , 259 mNOx , 264 mNOx , 267
mNOx265
mNOx275
mNOx290
mNOx , 532
mNO 196
mNO 140 NO 140 NO 140 NO 140
mNO, 139 mNO
139
mNO137
mNO, 200
NO2 346
NO2 119NO2 121 NO2 125
mNO2, 128 mNO2130
mNO2139
mNO2152
mNO2, 332
7.58 14.4318.48
50
100
150
200
250
300
350
400
450
500
550
600
0 5 10 15 20 25 30 35 40
ppm
time(min)
7jul08b NO2 mode down 1SCR
spray 36,34,32,30,24,off
eNOx
mNOx
mNO
mNO2
spray
36ms4.55min
34ms6.85min
32ms4.05min
30ms6.42min
28ms2.13min
26ms1.9min
24ms2.78min
off9.77min
SUM523
SUM 927SUM 858
SUM 777
SUM 708
SUM650
SUM600SUM 512mNOx , 500
mNOx 240 mNOx 244
mNOx250
mNOx252
mNOx255mNOx260
mNOx290
NH3 , 680
NH3 , 614
mNH3513
mNH3 450
mNH3395 mNH3 312
NH3 222
0
100
200
300
400
500
600
700
800
900
1000
0 2 4 6 8 10 12 14 16 18 20 22 24 26 28
ppm
time(min)
9jul08b NH3 dw 1scr Lspray 36,34,32,30,28,26,24
exsa NOx ppm
SUM
mNOx
spray V
36 2628303234 24spray
off
B-3
Appendix 4.1.5b SUM in and SUM out average for 1 SCR with spray
1scr spray variance
SUM INrefn 15/7L 15/7R 9/7L 9/7R 7/7d Data 4 CFDspray sum1 sum2 sum3 sum4 sum5 sumINavg std dev INupper limINlower lim NO in
36 36 716 741 785 800 761 39 799 722 19634 34 690 720 757 766 835 754 55 808 699 19632 32 646 700 750 740 833 734 69 803 665 19630 30 636 670 730 737 841 723 78 801 644 19628 28 626 650 704 718 802 700 68 768 632 19626 26 616 616 685 688 797 680 74 755 606 19624 24 580 591 650 657 746 645 66 711 579 196off 0 543 565 540 541 563 550 12 563 538 196
SUM OUTrefn 15/7L 15/7R 9/7L 9/7R 7/7c Data 4 CFDspray sumA sumB sumC sumD sumE sumOUTavg std dev OUTupper OUTlower NO out
36 36 850 750 927 822 968 863 86 950 777 14034 34 780 700 858 736 909 797 86 883 710 14032 32 700 635 777 720 830 732 75 807 658 14030 30 550 590 708 691 766 661 89 750 572 14028 28 472 534 650 674 703 607 99 705 508 13926 26 514 470 600 610 625 564 68 632 496 13924 24 433 440 512 541 548 495 55 550 440 137off 0 539 550 523 516 562 539 19 558 520 200
sumINavg, 761754
734
723700680
645
sumOUTavg, 863
797
732
661
607564
495
196196196196196196196
140140140140139139137100
150
200
250
300
350
400
450
500
550
600
650
700
750
800
850
900
950
1000
22 24 26 28 30 32 34 36 38
ppm
spray setting
SUM in & SUM out avg for 1scrNO in & NO out
sumINavg
sumOUTavg
NO in
NO out
exNOx , 559 exNOx , 563SUM 543
SUM , 716
690
646 636 626616
580
mNOx , 540
mNOx , 475 mNOx , 480 mNOx 486mNOx 493 mNOx 496 mNOx 500
mNOx , 526
NH3 235NH3 200
NH3 160 NH3 140
NH3 130NH3 115
NH3 65
6.23
0
100
200
300
400
500
600
700
800
900
0 2 4 6 8 10 12 14 16 18
ppm
time (min)
15jul08c Lspray 36-24 NH3 up1SCR
exNOx
SUM
mNOx
NH3
spray V
364.65m
262
282.08
301.58
321.69
342m
242.34
sprayoff
SUM591
616650
670700 720
SUM741
SUM 565
mNOx 517 511 500 485 480 476
mNOx , 472
mNOx , 536
NH3 65 NH3 70
NH3 100NH3 150
NH3 180
NH3 230NH3 , 244
NH3 , 275
0
100
200
300
400
500
600
700
800
900
17 19 21 23 25 27 29 31 33
ppm
time (min)
15jul08c Rspray 24-36 NH3 up1SCR
exNOx
BMEP bar
ex O2
etas O2
spray V
362.16
261.42
281.75
301.92
322.35
341.8
241.1
sprayoff
mSUM 541
mSUM 540
mSUM , 785757
750 730704
685650
mNOx , 420 mexa NOx , 422
mexa NOx , 425
mexa NOx ,430
mexa NOx 435
mexa Nox 442
mexa NOx 445
mexa NH3 360NH3 330
NH3 315NH3 290
NH3 270NH3 245
NH3 210150
250
350
450
550
650
750
850
4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
ppm
time(min)
09jul08c NH3 up 1scr spray 36, 34, 32, 30, 28, 26, 24 L
eNOx ppm
mSUM
mNOx
mNH3
spray V
36 242628303234
sprayoff
mSUM540
eNOx ppm, 554
mSUM , 657mSUM 688
mSUM , 718mSUM , 737 mSUM , 740
mSUM , 766mSUM , 800
mNOx 444 mNOx 437 mNOx 430 mNOx 424 mNOx 422 mNOx 420 mNOx , 410
mNH3 , 210
NH3 250
NH3 290 NH3 310mNH3 , 320
mNH3 , 345
mNH3 , 385
150
250
350
450
550
650
750
850
17 19 21 23 25 27 29 31
ppm
time(min)
09jul08c NH3 up 1scr spray 36, 34, 32, 30, 28, 26, 24 R
eNOx ppm
mSUM
mNOx
spray V
24 26 28 30 32 34 36
sprayoff
SUM541
SUM , 563
SUM , 835
SUM,833SUM 841
SUM802 SUM797SUM746
SUM , 563
mNOx , 531 mNOx , 450 mNOx446 mNOx441 mNOx444 mNOx445
mNOx451
mNOx , 513
NH3, 32
NH3, 385 NH3,387NH3,400
NH3,358 NH3,352
NH3,295
NH3, 54
0
200
400
600
800
1000
0 5 10 15 20 25 30 35 40 45 50
ppm
time(min)
7jul08d nh3 up 1scr spray 34,32,30,28,26,24,off
exsa NOx calc
SUM
mNOx
NH3
spray
34ms32ms
30ms 28ms 26ms 24msspray
exNOx, 551
SUM 539
mexSUM, 850780
700
550
472
514
433
mexNOx, 260 270 280 300320
300350
mexNH3, 580
510
415
250
160
215
100
0
200
400
600
800
0 5 10 15 20 25
ppm
time(min)
15jul08b NH3 dw 1scr spray 36-24 Left
exNOx
mexSUM
mNOx
mexNH3
spray V
36 2628303234 24spray
off
mexSUM, 440 470
534
590
635
700
750
mexSUM, 550
mNOx, 335mNOx, 315
mNOx,290
mNOx,280
275 mNOx, 270 mNOx, 265
mNOx, 532
mexNH3 110160
250
300
360
420
490
0
200
400
600
800
24 29 34 39 44 49
ppm
time(min)
15jul08b NH3 dw 1scr spray 24-36 Right
exNOx
mexSUM
mNOx
mexNH3
spray V
3626 28 30 32 3424spray
off
SUM 516SUM541
SUM610
SUM674SUM691
SUM720
SUM736
SUM 822
mNOx 287
mNOx 267 mNOx256
mNOx258
mNOx252 mNOx242 mNOx243 mNOx242NH3 251
NH3 332
NH3 414NH3 435
NH3 487
NH3 514
NH3 584
NH3 702
0
100
200
300
400
500
600
700
800
900
1000
25 30 35 40 45
ppm
time(min)
9jul08b NH3 dw 1scr Rspray 36,34,32,30,28,26,24
exsa NOx ppm
SUM
mNOx
NH3
spray V
3626 28 30 32 3424sprayoff
eNOx, 572SUM , 562
SUM 968 SUM ,909SUM 830
SUM766
SUM703SUM625
SUM548 SUM 562
mNOx , 548
mNOx , 262 mNOx , 265 mNOx266
mNOx266
mNOx268
mNOx , 270
mNOx 283
mNOx , 518
NH3 706 NH3 644
NH3 564NH3 500
NH3,435NH3,355
NH3,265
NH3 , 38
0
200
400
600
800
1000
1200
0 10 20 30 40 50 60
ppm
time(min)
7jul08c NH3down 1SCR, Spray 36,34,32,30,28,26,24,off
eNOx
SUM
mNOx
NH3
spray
34ms 32msmin
30msmin 28ms
min26ms
min24ms
min36ms
minspray
offspray
off
Dates: (1, 7,18,23,24 July 2008)
Appendix 4.1.6 Experimental data for Urea Spray: 4 SCR
240708b NO2
240708b NH
up 4 SCR L-R with spray
3
020708c NO
upstream 4 SCR L1-R1-L1
2
230708b NH
downstream 4 SCR with spray
3
Appendix 4.1.6b SUM in and SUM out average for 4 SCR with spray
downstream 4 SCR R1
180708c NH3
240708b NH
upstream 4 SCR spray 34-24 L-R
3
240708b NH
upstream 4 SCR spray L
3
upstream 4 SCR spray R
180708b NH3
230708b NH
downstream 4 SCR L - R
3
downstream 4 SCR L-R
B-4
exsa Nox, 583
mxNOx 523
mxNO, 194
mxNO 192
195 195mxNOx197
197mxNO, 200 (40%)
mxNO2 , 325 (60%)
50
100
150
200
250
300
350
400
450
500
550
600
36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
ppm
time (min)
24jul08b no2 up 4SCR L-RNO2=60% NO=40%
exsa Nox
mxSUM
mxNOx
mxNH3
spray V
2626283032
spray off
24
24
28 30 32 34
exsa Nox, 575
mxSUM 812
mxSUM , 830
mxSUM , 857mxSUM , 883
mxSUM , 906mxSUM , 931
mxSUM , 522mxNOx , 511mxNOx , 480 468 , 476 485 489 491
mxNOx , 493
mxNOx488
mxNOx478mxNOx473
mxNOx468mxNOx472
mxNOx , 192
mxNH3 , 443
410386
355330
313 318346
381405
434466 460 446 429
410377
mxNH3 , 328
0
100
200
300
400
500
600
700
800
900
1000
0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38
ppm
time (min)
24jul08b NH3 up 4SCR L1-R1-L2
exsa Nox
mxSUM
mxNOx
mxNH3
spray V
261.98m
282.34m30
1.95m32
2.73m34
4.72m
242.12m
261.73m
281.97m
301.96m
322.12m 34
2.4m
242.05m
241.15m
261.42m
281.7m
301.56m
321.72m
exNOx , 593
mNOx, 554
mNOx, 38
mNOx, 134
mNOx, 546
mNO 205
mNO, 2 mNO, 1 mNO, 1 mNO, 1 mNO, 5mNO 30
mNO, 205
NO2, 348
NO2, 5 NO2, 3NO2, 2 NO2, 1 NO2, 35
NO2, 100
NO2, 344
0
100
200
300
400
500
600
0 10 20 30 40 50 60 70
ppm
time(min)
020708c NO2 dw 4SCRspray 34-24
exNOx
mNOx
mNO
NO2
spray
26283032spray
off2434
exsNOx , 561
SUM , 79
SUM , 133SUM , 166 SUM , 224
SUM , 542
SUM , 311
SUM , 374
mNOx, 554
NH3, 79NH3, 136
NH3, 167
NH3, 225
NH3, 310
mexa NH3, 375
0
200
400
600
800
1000
50 55 60 65 70 75 80 85 90 95 100 105 110
ppm
time(min)
23jul08b NH3 dw 4SCR R1spray 34-24 ms 5 hz
exsa NOx SUM mNOxNH3spray V
243.72m
2614.71m
287.45m
308.12m
3215.19m
346.43
B-5
Appendix 4.1.6b SUM in and SUM out average for 4 SCR with spray
4scr spray variance
SUM INrefn 18jul08L 18julR 24/7L 24/R Data 4 CFDspray sum1 sum2 sum3 sum4 sumINavg std dev INupper limINlower lim NO in
36 36 875 940 908 46 953 86234 34 865 920 931 900 904 29 933 875 19432 32 850 880 906 875 878 23 901 855 19230 30 835 855 883 860 858 20 878 839 19528 28 820 835 857 835 837 15 852 822 19526 26 800 810 830 810 813 13 825 800 19724 24 785 790 812 800 797 12 809 785 197off 0 565 565 522 522 544 25 568 519 200
SUM OUTrefn 18jul08L 18julR 23/7L 23/R Data 4 CFDspray sumA sumB sumC sumD sumOUTavg std dev OUTupper OUTlower NO out
36 36 447 401 424 33 457 39134 34 384 349 375 361 367 15 383 352 232 32 326 284 311 295 304 18 322 286 130 30 266 242 224 235 242 18 260 224 128 28 200 184 166 175 181 15 196 167 126 26 141 122 133 115 128 12 139 116 524 24 94 78 79 60 78 14 92 64 30off 0 535 535 540 545 539 5 544 534 205
sumINavg, 908904
878858837813797
194192195195
197197
sumOUTavg, 424
367
304
242
181128
78
2111530
050
100150200250300350400450500550600650700750800850900950
1000
22 24 26 28 30 32 34 36 38
ppm
spray setting
avg 4scr sum in & sum out & NOin NO out
sumINavgNO insumOUTavgNO out
exsa Nox, 580sum565
SUM875 865
850 835 820800
785 790810
835855
880920
sum940
mxNOx 581534 521 514 512 514 514 513 512 507 500 495 490 491
494
mexa NH3, 350 343 334320 310
295275 278
315 332365
392428 450
200
300
400
500
600
700
800
900
1000
0 5 10 15 20 25 30 35 40
ppm
time (min)
18jul08c NH3 up 4scr spray 34-24 L-R
exsa Nox
mexa SUM
mexa NOx
mexa NH3
spray V
261.6m28
1.69m
301.71m32
1.65m
341.97m
241.82m36
3.17m26
2.08m
281.82m 30
2.13m
322.2m 34
2.1m
361.88m24
1.88m
spray offspray off
exsa Nox, 575
mxSUM 812
mxSUM , 830
mxSUM , 857mxSUM , 883
mxSUM , 906mxSUM , 931
mxSUM , 522491mxNOx , 493
mxNOx488
mxNOx478mxNOx473
mxNOx468mxNOx472
mxNOx , 192
313 318346
381405
434466 460 446 429
410377mxNH3 , 328
0
100
200
300
400
500
600
700
800
900
1000
14 16 18 20 22 24 26 28 30 32 34 36 38
ppm
time (min)
24jul08b NH3 up 4SCR L
exsa Nox
mxSUM
mxNOx
mxNH3
spray V
24 26 28 30 32 34 242628303234 spray off
sum 522
sum 900sum 875
sum860sum835
sum810 sum800
mxNOx , 511 mxNOx , 480 468 , 476 485 489 491
mxNH3 , 443
410386
355330
313
0
100
200
300
400
500
600
700
800
900
1000
0 2 4 6 8 10 12 14 16
ppm
time (min)
24jul08b NH3 up 4SCR R
exsa Nox
mxSUM
mxNOx
mxNH3
spray V
2628303234
spray off
24
exsa NOx , 578
sum447
mexa NOx , 0
384
326
266
200
141
94sum78
122
184
242
284
349
sum401
-50
50
150
250
350
450
550
0 20 40 60 80 100 120
ppm
time (min)
18jul08b NH3 down 4 SCR spray 36-24 L - R
exsa NOx
mexa SUM
mexa NOx
mexa NH3
spray V
36 262830323424
3626 28 30 32 3424
24spray
off
exsNOx , 561
SUM , 79133
SUM224
SUM 311
375
sum 545
mNOx, 554
sum540
166
361
295
235
175115
600
200
400
600
800
1000
50 55 60 65 70 75 80 85 90 95 100 105 110 115 120 125 130 135 140 145 150 155 160
ppm
time(min)
23jul08b NH3 dw 4SCR L - Rspray 34-24 ms 5 hz
exsa NOx SUM mNOxNH3spray V
24 26 28 30 32 34 2628303234 24 spray offMEXA
purge
spray off
Appendix 4.2.5 Experimental data for 5% NH3
Dates: (Final 5%gas 12, 21 august 2008)
gas: 1 SCR
120808b NH3
120808c NH
upstream 1 SCR 5% gas
3
210808c NO downstream 1 SCR 5% gas
downstream 1 SCR 5% gas
210208 NO downstream 1 SCR 5%-manual log in log book (Appendix 4.2.5b)
B-6
exNOx 575
exNOx , 575exNOx 580
mSUM >1004mSUM , 964
mSUM , 845mSUM , 780
mSUM 725
mSUM , 620mSUM 575 mSUM 565
mNOx 452 mNOx 463 mNOx 473mNOx 485 mNOx 491 mNOx , 511
mNOx 537
NH3 636
NH3 523
NH3 385
NH3 309NH3 245
NH3 , 111
NH3 , 430
100
200
300
400
500
600
700
800
900
1000
1100
17 18 19 20 21 22 23 24 25
ppm
time(min)
12aug08b bNH3 up1SCR 5% L2
exNOx
mSUM
mNOx
NH3
spray
320.2psi
480.4psi
600.5psi
800.7psi
961psi
160.1psi
gas off0
exNOx , 589
mSUM , 669
mSUM , 579
mSUM , 495mSUM , 476 mSUM , 470
mSUM , 513
mSUM , 578
mSUM 569
mNOx 295
mNOx , 310mNOx , 338
mNOx , 366mNOx , 389
mNOx 468
mNOx , 540 mNOx , 539
NH3 389
NH3 , 279
NH3 , 168
NH3 , 114NH3 , 82
NH3 , 46NH3 , 38 NH3 , 34
0
100
200
300
400
500
600
700
800
21 22 23 24 25 26 27 28 29 30
ppm
time(min)
12aug08c NH3 dw1scr 5% L2
exNOx
mSUM
BMEP
spray
320.2psi
600.5psi
800.7psi
961psi
160.1psi
gas off
0480.4psi
NO, 231
NO, 1
NO, 66
NO, 97
NO, 126
NO, 187
NO 229 NO 231
NO, 191
NO, 130
NO, 102
NO, 67
NO, 18
NO, 0
NO, 231
0
50
100
150
200
250
10.00 15.00 20.00 25.00 30.00 35.00 40.00
ppm
time(min)
210808c NO dw 1 scr with 5%exsa1500 dw1scr Gas flow 96-16(glass float)
NO
Gas off Gas off
96 96
80
60
48
32
16
80
60
48
32
16
00
534
304312
341355
380
465
536
159
119110113116121142160
378
192202
227240
266
325
371
0
100
200
300
400
500
600
0 20 40 60 80 100 120
ppm
gas setting
21aug08 NO2 down 1SCR 5% gas manual log
NOx
NO
NO2
B-6b
Appendix 4.2.5b NO dw 1 SCR with 5% ammonia gas - Manual log from mexa
Date of test : 210808Test condition 1500 rpm & 6 Bar bmep
Gas setting NO reading 1 NO reading 2 Avg 33% var0 160 162 161 214.13
16 142 142 142 188.8632 121 122 122 161.6048 116 118 117 155.6160 113 113 113 150.2980 110 112 111 147.6396 119 115 117 155.61
50
70
90
110
130
150
170
190
210
230
0 20 40 60 80 100 120
NO, ppm
5% NH3 gas injection setting
5% Gas & 1 SCR MEXA NO readings
Mean
Appendix 4.2.6 Experimental data for 5% NH3 gas: 2 SCR
110808b NH
Date: (11 august 2008)
3
110808c NH
upstream 2 SCR 5% gas
3
210808c NO downstream 1 SCR 5% gas (refer to Appendix 4.2.5)
downstream 2 SCR 5% gas
B-7
exNOx, 578
exNOx, 585
mSUM, 1000
mSUM, 935
mSUM, 824
mSUM, 770
mSUM, 710
mSUM, 608mSUM, 567
mNOx, 463 mNOx, 472
mNOx, 487 mNOx, 495mNOx, 504 mNOx, 514
mNOx, 542
NH3 589
NH3 , 482
NH3 , 352
NH3 , 282
NH3 , 218
NH3 , 98
NH3 , 31
0
100
200
300
400
500
600
700
800
900
1000
1100
17 18 19 20 21 22 23 24
ppm
time(min)
11aug08b NH3 up2SCR 5% gas L2
exNOx
mSUM
mNOx
NH3
spray
320.2psi
480.4psi
600.5psi
961psi
160.1psi 080
0.7psi
exNOx, 593
mSUM, 14
mSUM, 101
mSUM, 226
mSUM, 297
mSUM, 361
mSUM, 476
mSUM, 556
mNOx, 9
mNOx, 100
mNOx, 224
mNOx, 297
mNOx, 354
mNOx, 470
mNOx, 548
NH3 , 4
NH3 , 3 NH3 , 3 NH3 , 4 NH3 , 7 NH3 , 6 NH3 , 6
0
100
200
300
400
500
600
20 22 24 26 28 30 32
ppm
time (min)
11aug08c NH3 dw2scr 5%
exNOx
mSUM
mNOx
NH3
spray
320.2psi
480.4psi
600.5ps
800.7psi
961psi
160.1psi
0
Appendix 4.2.7 Experimental data for 5% NH3 gas: 3 SCR
070808b NH
Date: (7 august 2008)
3
070808c NH
upstream 3 SCR 5% gas
3
downstream 3 SCR 5% gas
B-8
576 exNOx, 582
mSUM, >1000956
mSUM, 835mSUM, 777
mSUM, 729
mSUM, 628mSUM, 583
mNOx, 462
mNOx, 474
mNOx, 483 mNOx, 496 mNOx, 505 mNOx, 520
mNOx, 550
NH3 , 618
NH3 , 500
NH3 , 371
NH3 , 295NH3 , 236
NH3 , 104
NH3 , 32
0
100
200
300
400
500
600
700
800
900
1000
1100
1200
18 19 20 21 22 23 24 25 26
ppm
time(min)
070808b NH3 up3SCR 5% gas L2
exNOx
mSUM
mNOx
NH3
spray
320.2psi
480.4psi
600.5psi
800.7psi
961psi 016
0.1psi
exNOx, 590
exNOx, 593
mSUM, 11
mSUM, 95
mSUM, 244
mSUM, 309
mSUM, 373
mSUM, 490
mSUM, 566
mNOx 7
mNOx, 91
mNOx, 238
mNOx, 305
mNOx, 360
mNOx, 480
mNOx, 553
NH3 , 1NH3 , 2
NH3 , 5 NH3 , 7 NH3 , 9 NH3 , 10 NH3 , 10
-50
0
50
100
150
200
250
300
350
400
450
500
550
600
650
24 25 26 27 28 29 30 31 32 33 34 35
ppm
time(min)
070808c NH3 dw3SCR 5% gas L2
exNOx
mSUM
mNOx
NH3
spray
320.2psi
480.4psi60
0.5psi80
0.7psi
961psi 16
0.1psi
0
Appendix 4.2.8 Experimental data for 5% NH3 gas: 4 SCR
060808b NH
Dates: (16, 25 jun2008 & 5, 6 august 2008)
3
060808e NH
upstream 4 SCR 5% gas
3
060808c NO
downstream 4 SCR 5% gas
2
060808d NO
upstream 4 SCR 5% gas
2
downstream 4 SCR 5% gas
B-9
exNOx 560exNOx 560
mSUM, 545
mSUM >1003
mSUM, 935
mSUM, 826
mSUM, 757
mSUM, 700
mSUM, 600mSUM, 550
mxNOx535
mxNOx 450mxNOx465
mxNOx473
mxNOx476
mxNOx 484mxNOx500
mxNOx 520
NH3 , 15
NH3 600
NH3 484
NH3 362
NH3 286
NH3 220
NH3 100
NH3 30
0
100
200
300
400
500
600
700
800
900
1000
1100
0 2 4 6 8 10 12 14
ppm
time (min)
060808b NH3 up4SCR( 5% gas) 96-0 glass float
exNOx
mSUM
mxNOx
NH3
spray
320.2psi
480.4psi
600.5psi
800.7psi
961psi 016
0.1psigas off
exNOx , 573mSUM , 550
mSUM , 8mSUM , 87
mSUM , 217
mSUM 283
mSUM353
mSUM , 472
mSUM , 550
mNOx , 533
mNOx , 4mNOx , 83
mNOx 210
mNOx 275
mNOx 344
mNOx 460mNOx , 536
NH3 , 11 NH3 , 3 NH3 , 4NH3 , 6
NH3 , 8
NH3 , 10NH3 11
NH3 , 14
0
50
100
150
200
250
300
350
400
450
500
550
600
0 2 4 6 8 10 12 14 16 18 20 22 24 26
ppm
time(min)
060808e NH3 dw4SCR (5%gas)
exNOx
mSUM
mNOx
NH3
spray
320.2psi
480.4psi
600.5psi
800.7psi
961psi 016
0.1psigas off
exNOx , 567
mNOx,538
mNOx485 mNOx494 mNOx 497 mNOx, 500 mNOx, 505mNOx, 518 mNOx, 536
mNO, 210 mNO, 207 mNO, 210 mNO, 210 mNO, 212 mNO, 212 NO 213 mNO, 213
mNO2, 328
mNO2 280 mNO2, 284 mNO2, 287 mNO2, 288 mNO2, 293 mNO2, 305mNO2, 323
0
50
100
150
200
250
300
350
400
450
500
550
600
2 4 6 8 10 12 14 16
ppm
time (min)
060808c NO2 up4SCR 5%gas NO2=60% NO=40%
exNOx
mNOx
mNO
mNO2
spray
320.2psi
480.4psi
600.5psi
800.7psi
961psi 016
0.1psigas off
exNOx , 573 exNOx , 574
mNOx 535
mNOx 5
mNOx , 80
mNOx , 210
mNOx 278
mNOx , 335
mNOx460
mNOx,536
mNO, 212
mNO, 2mNO, 25 mNO, 75
mNO100mNO, 122
mNO,170
mNO, 214
mNO2, 323
mNO2, 3mNO2, 55
mNO2, 135
mNO2 178
mNO2, 213
mNO2 282
mNO2, 322
0
50
100
150
200
250
300
350
400
450
500
550
600
0 2 4 6 8 10 12 14 16 18 20
ppm
time(min)
060808d NO2 d 4SCR 5% NO2=60% NO=40%
exNOx
mNOx
mNO
mNO2
spray
320.2psi
480.4psi
600.5psi
800.7psi
961psi
016
0.1psi
gas off
Appendix 4.2.9 Experimental data for 1 SCR 4% NH3
Dates: (4% gas- 10, 11,12,16,24 jun2008)
gas
100608b NH3
100608c NO upstream 1 SCR 4% gas
upstream 1 SCR 4% gas
100608b NH3
100608d NO
downstream 1 SCR 4% gas
2
downstream 1 SCR 4% gas
B-10
eNOx , 623.4
mNOx, 931.7
mNOx, 584
mNOx, 500SUM477.3
SUM 450.9 SUM 439
sum, 576
mNO, 855.6
mNO, 206 mNO, 206.3
mNO, 202.9
mNO, 202.7 mNO, 203.1 mNO, 209.3
NO2, 79.6
NO2, 378
NO2, 293.7NO2, 274.4
NO2, 248.2 NO2, 235.9
NO2, 366.7
0
100
200
300
400
500
600
700
800
900
1000
0 5 10 15 20 25 30
ppm
time(min)
100608c NO up1SCR4%
eNOx
mNOx
mNO
NO2
spray V
gas 0 gas offgas 50 gas 75 gas 100 gas 120
exNOx , 618
sum1121
sum869
SUM579
468
sum471
sum 600
sum449
NH3836
NH3625
NH3333
NH3169 NH3 ,
1424
21.8
NH342.9
81.7
NH3 , 450
100
200
300
400
500
600
700
800
900
1000
1100
60 65 70 75 80 85 90 95 100 105
ppm
time (min)
10jun08b nh3 downstream 1 scr 4%
exNOx
SUM
mNOx
NH3
Gas trigger
Gas0
Gas20 Gas
40
Gas0
Gas30
Gas120 Gas
100
Gas0ff
Gas75 Gas
50
exNOx, 620.5
mNOx, 573.4
mNOx, 248.8
262.6281.9
319.3
mNOx, 571.8
mNO, 206.3
151.6 149.4 148.7mNO, 148.1
mNO, 210.3
NO2, 369.8
101.4116.8
135.3
NO2, 176.1
NO2, 364.9
0
100
200
300
400
500
600
700
0 2 4 6 8 10 12 14 16 18 20
ppm
time(min)
100608d NO dw1scr4%
exNOx
mNOx
mNO
NO2
spray trigger V
gas120
gas0 gas
75gas100
gas0
gas50
engine cooldown
Appendix 4.9.1a Excel numerical integration- 4% gas 4SCR
B-11
*In this appendix, portion of the time interval from 227 to 742 was not visible.
The overall time interval involved of ammonia slip was from 220 to 753 seconds
This appendix is just a preview of the whole numerical integration from 220 to 753 seconds
For details of the ammonia slip trace, please refer to figure 4.9.1a
*
Appendix 4.9.2a Excel numerical integration- Urea spray 4SCR
B-12
*In this appendix, portion of the time interval from 279 to 946 was not visible.
The overall time interval involved of ammonia slip was from 270 to 956 seconds
This appendix is just a preview of the whole numerical integration from 270 to 956 seconds
For details of the ammonia slip trace, please refer to figure 4.9.2
*